8,481 research outputs found
Hurdles for Recent Measures in Eternal Inflation
In recent literature on eternal inflation, a number of measures have been
introduced which attempt to assign probabilities to different pocket universes
by counting the number of each type of pocket according to a specific
procedure. We give an overview of the existing measures, pointing out some
interesting connections and generic predictions. For example, pairs of vacua
that undergo fast transitions between themselves will be strongly favored. The
resultant implications for making predictions in a generic potential landscape
are discussed. We also raise a number of issues concerning the types of
transitions that observers in eternal inflation are able to experience.Comment: 15 PRD-style pages, 5 figures, expanded discussion of measures in
Sec. II, added reference
Towards observable signatures of other bubble universes II: Exact solutions for thin-wall bubble collisions
We assess the effects of a collision between two vacuum bubbles in the
thin-wall limit. After describing the outcome of a generic collision possessing
the expected hyperbolic symmetry, we focus on collisions experienced by a
bubble containing positive vacuum energy, which could in principle contain our
observable universe. We provide criteria governing whether the post-collision
domain wall accelerates towards or away from this "observation" bubble, and
discuss the implications for observers located at various positions inside of
the bubble. Then, we identify the class of solutions which have minimal impact
on the interior of the observation bubble, and derive a simple formula for the
energy density of a shell of radiation emitted from such a collision. In the
context of a universe undergoing false vacuum eternal inflation, these
solutions are perhaps the most promising candidates for collisions that could
exist within our past light cone, and therefore in principle be observable.Comment: 18 PRD-style pages, 12 figures. Added appendix on the expected number
of collisions, added references, minor correction to Appendix C, conclusions
unchanged. Replaced to match published versio
Electrovac Universes with a Cosmological Constant
We present the extension of the Einstein-Maxwell system called electrovac
universes by introducing a cosmological constant . In the absence of
the term, the crucial equation in solving the Einstein-Maxwell system
is the Laplace equation. The cosmological constant modifies this equation to
become in a non-linear partial differential equation which takes the form
. We offer special solutions of this equation.Comment: 7 page
Schemata as Building Blocks: Does Size Matter?
We analyze the schema theorem and the building block hypothesis using a
recently derived, exact schemata evolution equation. We derive a new schema
theorem based on the concept of effective fitness showing that schemata of
higher than average effective fitness receive an exponentially increasing
number of trials over time. The building block hypothesis is a natural
consequence in that the equation shows how fit schemata are constructed from
fit sub-schemata. However, we show that generically there is no preference for
short, low-order schemata. In the case where schema reconstruction is favoured
over schema destruction large schemata tend to be favoured. As a corollary of
the evolution equation we prove Geiringer's theorem. We give supporting
numerical evidence for our claims in both non-epsitatic and epistatic
landscapes.Comment: 17 pages, 10 postscript figure
Towards observable signatures of other bubble universes
We evaluate the possibility of observable effects arising from collisions
between vacuum bubbles in a universe undergoing false-vacuum eternal inflation.
Contrary to conventional wisdom, we find that under certain assumptions most
positions inside a bubble should have access to a large number of collision
events. We calculate the expected number and angular size distribution of such
collisions on an observer's "sky," finding that for typical observers the
distribution is anisotropic and includes many bubbles, each of which will
affect the majority of the observer's sky. After a qualitative discussion of
the physics involved in collisions between arbitrary bubbles, we evaluate the
implications of our results, and outline possible detectable effects. In an
optimistic sense, then, the present paper constitutes a first step in an
assessment of the possible effects of other bubble universes on the cosmic
microwave background and other observables.Comment: 17 PRD-style pages including 13 embedded figures. Minor corrections
to figures 4 and 7 and added discussion in Sec. III.E.2 and
Two Tunnels to Inflation
We investigate the formation via tunneling of inflating (false-vacuum)
bubbles in a true-vacuum background, and the reverse process. Using effective
potentials from the junction condition formalism, all true- and false-vacuum
bubble solutions with positive interior and exterior cosmological constant, and
arbitrary mass are catalogued. We find that tunneling through the same
effective potential appears to describe two distinct processes: one in which
the initial and final states are separated by a wormhole (the Farhi-Guth-Guven
mechanism), and one in which they are either in the same hubble volume or
separated by a cosmological horizon. In the zero-mass limit, the first process
corresponds to the creation of an inhomogenous universe from nothing, while the
second mechanism is equivalent to the nucleation of true- or false-vacuum
Coleman-De Luccia bubbles. We compute the probabilities of both mechanisms in
the WKB approximation using semi-classical Hamiltonian methods, and find that
-- assuming both process are allowed -- neither mechanism dominates in all
regimes.Comment: 16 PRD-style pages, 13 figures. PRD, in press. Revised to match
published versio
Dynamics and instability of false vacuum bubbles
This paper examines the classical dynamics of false vacuum regions embedded
in surrounding regions of true vacuum, in the thin-wall limit. The dynamics of
all generally relativistically allowed solutions -- most but not all of which
have been previously studied -- are derived, enumerated, and interpreted. We
comment on the relation of these solutions to possible mechanisms whereby
inflating regions may be spawned from non-inflating ones. We then calculate the
dynamics of first order deviations from spherical symmetry, finding that many
solutions are unstable to such aspherical perturbations. The parameter space in
which the perturbations on bound solutions inevitably become nonlinear is
mapped. This instability has consequences for the Farhi-Guth-Guven mechanism
for baby universe production via quantum tunneling.Comment: 16 PRD-style pages including 11 embedded figures; accepted by PRD.
Revised version includes new solution, discussion of 'thermal activation',
added reference, fixed typo
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