243 research outputs found
Special geometry, black holes and Euclidean supersymmetry
We review recent developments in special geometry and explain its role in the
theory of supersymmetric black holes. To make this article self-contained, a
short introduction to black holes is given, with emphasis on the laws of black
hole mechanics and black hole entropy. We also summarize the existing results
on the para-complex version of special geometry, which occurs in Euclidean
supersymmetry. The role of real coordinates in special geometry is illustrated,
and we briefly indicate how Euclidean supersymmetry can be used to study
stationary black hole solutions via dimensional reduction over time.
This article is an updated and substantially extended version of the previous
review article `New developments in special geometry', hep-th/0602171.Comment: 39 pages, Contribution to the Handbook on Pseudo-Riemannian Geometry
and Supersymmtry, ed. V. Corte
Duality and black hole partition functions
Supersymmetric black holes provide an excellent theoretical laboratory to
test ideas about quantum gravity in general and black hole entropy in
particular. When four-dimensional supergravity is interpreted as the low-energy
approximation of ten-dimensional string theory or eleven-dimensional M-theory,
one has a microscopic description of the black hole which allows one to count
microstates and to compare the result to the macroscopic (geometrical) entropy.
Recently it has been conjectured that there is a very direct connection between
the partition function of the topological string and a partition function for
supersymmetric black holes. We review this idea and propose a modification
which makes it compatible with electric-magnetic duality.Comment: 5 pages, based on talk given at the 11th Marcel Grossmann meeting,
Berlin, July 23-29, 200
Dynamical symmetry enhancement near N=2, D=4 gauged supergravity horizons
We show that all smooth Killing horizons with compact horizon sections of
4-dimensional gauged N=2 supergravity coupled to any number of vector
multiplets preserve supersymmetries, where
is a pull-back of the Hodge bundle of the special K\"ahler manifold on the
horizon spatial section. We also demonstrate that all such horizons with
exhibit an SL(2,R) symmetry and preserve either 4 or 8
supersymmetries. If the orbits of the SL(2,R) symmetry are 2-dimensional, the
horizons are warped products of AdS2 with the horizon spatial section.
Otherwise, the horizon section admits an isometry which preserves all the
fields. The proof of these results is centered on the use of index theorem in
conjunction with an appropriate generalization of the Lichnerowicz theorem for
horizons that preserve at least one supersymmetry. In all
cases, we specify the local geometry of spatial horizon sections and
demonstrate that the solutions are determined by first order non-linear
ordinary differential equations on some of the fields.Comment: 60 pages, late
Effective Actions near Singularities
We study the heterotic string compactified on K3 x T^2 near the line T=U,
where the effective action becomes singular due to an SU(2) gauge symmetry
enhancement. By `integrating in' the light W^\pm vector multiplets we derive a
quantum corrected effective action which is manifestly SU(2) invariant and
non-singular. This effective action is found to be consistent with a residual
SL(2,Z) quantum symmetry on the line T=U. In an appropriate decompactification
limit, we recover the known SU(2) invariant action in five dimensions.Comment: 33 pages, LaTeX. v2: cosmetic correction on titlepage. v3: references
and note adde
The effects of inhomogeneities on the cosmology of type IIB conifold transitions
In this paper we examine the evolution of the effective field theory
describing a conifold transition in type IIB string theory. Previous studies
have considered such dynamics starting from the cosmological approximation of
homogeneous fields, here we include the effects of inhomogeneities by using a
real-time lattice field theory simulation. By including spatial variations we
are able to simulate the effect of currents and the gauge fields which they
source. We identify two different regimes where the inhomogeneities have
opposite effects, one where they aid the system to complete the conifold
transition and another where they hinder it. The existence of quantized fluxes
in related systems has lead to the speculation that (unstable) string solutions
could exist, using our simulations we give strong evidence that these
string-like defects do not form.Comment: 11 pages, 2 figures. Published versio
Supergravity on R4 x S1/Z2 and singular Calabi-Yaus
We discuss the moduli space singularities that are generally present in
five-dimensional vector-coupled supergravity on a spactime of the form R4 x
S1/Z2, with vector fields surviving on the Z2 fixed planes. The framework of
supergravity is necessarily ambiguous when it comes to the non-singular
embedding theory, so we focus on those models coming from Calabi-Yau
three-folds with wrapped membranes.Comment: 13 p
Wald's entropy is equal to a quarter of the horizon area in units of the effective gravitational coupling
The Bekenstein-Hawking entropy of black holes in Einstein's theory of gravity
is equal to a quarter of the horizon area in units of Newton's constant. Wald
has proposed that in general theories of gravity the entropy of stationary
black holes with bifurcate Killing horizons is a Noether charge which is in
general different from the Bekenstein-Hawking entropy. We show that the Noether
charge entropy is equal to a quarter of the horizon area in units of the
effective gravitational coupling on the horizon defined by the coefficient of
the kinetic term of specific graviton polarizations on the horizon. We present
several explicit examples of static spherically symmetric black holes.Comment: 20 pages ; added clarifications, explanations, new section on the
choice of polarizations, results unchanged; replaced with published versio
The role of toll-like receptors (TLRs) in bacteria-induced maturation of murine dendritic cells (DCs) - Peptidoglycan and lipoteichoic acid are inducers of DC maturation and require TLR2
Toll-like receptors (TLRs) have been found to be key elements in pathogen recognition by the host immune system. Dendritic cells (DCs) are crucial for both innate immune responses and initiation of acquired immunity. Here we focus on the potential involvement of TLR ligand interaction in DC maturation. TLR2 knockout mice and mice carrying a TLR4 mutation (C3H/HeJ) were investigated for DC maturation induced by peptidoglycan (PGN), lipopolysaccharide (LPS), or lipoteichoic acids (LTAs). All stimuli induced maturation of murine bone marrow-derived DCs in control mice. TLR2− /− mice lacked maturation upon stimulation with PGN, as assessed by expression of major histocompatibility complex class II, CD86, cytokine, and chemokine production, fluorescein isothiocyanate-dextran uptake, and mixed lymphocyte reactions, while being completely responsive to LPS. A similar lack of maturation was observed in C3H/HeJ mice upon stimulation with LPS. DC maturation induced by LTAs from two different types of bacteria was severely impaired in TLR2− /−, whereas C3H/HeJ mice responded to LTAs in a manner similar to wild-type mice. We demonstrate that DC maturation is induced by stimuli from Gram-positive microorganisms, such as PGN and LTA, with similar efficiency as by LPS. Finally, we provide evidence that TLR2 and TLR4 interaction with the appropriate ligand is essential for bacteria-induced maturation of DCs
Cosmological Solutions, a New Wick-Rotation, and the First Law of Thermodynamics
We present a modified implementation of the Euclidean action formalism suitable for studying the thermodynamics of a class of cosmological solutions containing Killing horizons. To obtain a real metric of definite signature, we perform a `triple Wick-rotation' by analytically continuing all space-like directions. The resulting Euclidean geometry is used to calculate the Euclidean on-shell action, which defines a thermodynamic potential. We show that for the vacuum de Sitter solution, planar solutions of Einstein-Maxwell theory and a previously found class of cosmological solutions of N = 2 supergravity, this thermodynamic potential can be used to define an internal energy which obeys the first law of thermodynamics. Our approach is complementary to, but consistent with the isolated horizon formalism. For planar Einstein-Maxwell solutions, we find dual solutions in Einstein-anti-Maxwell theory where the sign of the Maxwell term is reversed. These solutions are planar black holes, rather than cosmological solutions, but give rise, upon a standard Wick-rotation to the same Euclidean action and thermodynamic relations
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