On Warped String Vacuum Profiles and Cosmologies, I. Supersymmetric Strngs. (arXiv:2109.06852v1 [hep-th])
<a href="http://arxiv.org/find/hep-th/1/au:+Mourad_J/0/1/0/all/0/1">J. Mourad</a>, <a href="http://arxiv.org/find/hep-th/1/au:+Sagnotti_A/0/1/0/all/0/1">A. Sagnotti</a>

We investigate in detail solutions of supergravity that involve warped
products of flat geometries of the type M(p+1) x R x T(D-p-2) depending on a
single coordinate. In the absence of fluxes, the solutions include flat space
and Kasner-like vacua that break all supersymmetries. In the presence of a
symmetric flux, there are three families of solutions that are characterized by
a pair of boundaries and have a singularity at one of them, the origin. The
first family comprises supersymmetric vacua, which capture a universal limiting
behavior at the origin. The first and second families also contain
non–supersymmetric solutions whose behavior at the other boundary, which can
lie at a finite or infinite distance, is captured by the no–flux solutions.
The solutions of the third family have a second boundary at a finite distance
where they approach again the supersymmetric backgrounds. These vacua exhibit a
variety of interesting scenarios, which include compactifications on finite
intervals and (p+1)-dimensional effective theories where the string coupling
has an upper bound. We also build corresponding cosmologies, and in some of
them the string coupling can be finite throughout the evolution.

We investigate in detail solutions of supergravity that involve warped
products of flat geometries of the type M(p+1) x R x T(D-p-2) depending on a
single coordinate. In the absence of fluxes, the solutions include flat space
and Kasner-like vacua that break all supersymmetries. In the presence of a
symmetric flux, there are three families of solutions that are characterized by
a pair of boundaries and have a singularity at one of them, the origin. The
first family comprises supersymmetric vacua, which capture a universal limiting
behavior at the origin. The first and second families also contain
non–supersymmetric solutions whose behavior at the other boundary, which can
lie at a finite or infinite distance, is captured by the no–flux solutions.
The solutions of the third family have a second boundary at a finite distance
where they approach again the supersymmetric backgrounds. These vacua exhibit a
variety of interesting scenarios, which include compactifications on finite
intervals and (p+1)-dimensional effective theories where the string coupling
has an upper bound. We also build corresponding cosmologies, and in some of
them the string coupling can be finite throughout the evolution.

http://arxiv.org/icons/sfx.gif