Prof Subir Sarkar

Implementing quadratic supergravity inflation

ArXiv hep-ph/9908380 (1999)

Authors:

Gabriel German, Graham Ross, Subir Sarkar

Abstract:

We study inflation driven by a slow-rolling inflaton field, characterised by a quadratic potential, and incorporating radiative corrections within the context of supergravity. In this model the energy scale of inflation is not overly constrained by the requirement of generating the observed level of density fluctuations and can have a physically interesting value, e.g. the supersymmetry breaking scale of $10^{10}$ GeV or the electroweak scale of $10^3$ GeV. In this mass range the inflaton is light enough to be confined at the origin by thermal effects, naturally generating the initial conditions for a (last) stage of inflation of the new inflationary type.

Implementing quadratic supergravity inflation

(1999)

Authors:

Gabriel German, Graham Ross, Subir Sarkar

Summary of the NOW'98 Phenomenology Working Group

ArXiv hep-ph/9906251 (1999)

Authors:

SM Bilenky, A Geiser, C Giunti, S Mohanty, S Otwinowski, S Sarkar, ZZ Xing

Abstract:

Summary of the Phenomenology Working Group at the Europhysics Neutrino Oscillation Workshop (NOW'98), 7-9 September 1998, Amsterdam.

Big Bang Nucleosynthesis: Reprise

(1999)

Big bang nucleosynthesis limit on N_nu

ArXiv hep-ph/9901404 (1999)

Authors:

E Lisi, Subir Sarkar, FL Villante

Abstract:

Recently we presented a simple method for determining the correlated uncertainties of the light element abundances expected from big bang nucleosynthesis, which avoids the need for lengthy Monte Carlo simulations. We now extend this approach to consider departures from the Standard Model, in particular to constrain any new light degrees of freedom present in the thermal plasma during nucleosynthesis. Since the observational situation regarding the inferred primordial abundances has not yet stabilized, we present illustrative bounds on the equivalent number of neutrino species N_nu for various combinations of individual abundance determinations. Our 95% C.L. bounds on N_nu range between 2 and 4, and can easily be reevaluated using the technique provided when the abundances are known more accurately.