Particle theory

The topological susceptibility and pion decay constant from lattice QCD

(2000)

Authors:

UKQCD Collaboration, A Hart, M Teper

Thermalisation after inflation

ArXiv hep-ph/0009078 (2000)

Authors:

Sacha Davidson, Subir Sarkar

Abstract:

During (re)heating of the universe after inflation, the relativistic decay products of the inflaton field $\phi$ must lose energy and additional particles must be produced to attain a thermalised state at a temperature $T_{\reh}$. We estimate the rate of energy loss via elastic and inelastic scattering interactions. Elastic scattering is an inefficient energy loss mechanism so inelastic processes, although higher order in the coupling $\alpha$, can be faster because more energy is transfered. The timescale to produce a particle number density of ${\cal O}(T_{\reh}^3)$ is the inelastic energy loss timescale, $\sim(\alpha^3 n_\phi/T_{\reh}^2)^{-1}$.

Thermalisation after inflation

(2000)

Authors:

Sacha Davidson, Subir Sarkar

Solar neutrino oscillation from large extra dimensions

(2000)

Authors:

Andre Lukas, Pierre Ramond, Andrea Romanino, Graham G Ross

Compact hyperbolic extra dimensions: branes, kaluza-klein modes, and cosmology.

Phys Rev Lett 85:5 (2000) 928-931

Authors:

N Kaloper, J March-Russell, GD Starkman, M Trodden

Abstract:

We reconsider theories with low gravitational (or string) scale M(*) where Newton's constant is generated via new large-volume spatial dimensions, while standard model states are localized to a 3-brane. Utilizing compact hyperbolic manifolds we show that the spectrum of Kaluza-Klein modes is radically altered. This allows the early Universe to evolve normally up to substantial temperatures, and completely negates the astrophysical constraints on M(*). Furthermore, an exponential hierarchy between the usual Planck scale and the true fundamental scale of physics can emerge with only O(1) coefficients. The linear size of the internal space remains small. The proposal has striking testable signatures.