Stabilization of Sub-Millimeter Dimensions: The New Guise of the Hierarchy Problem

TL;DR

This paper explores mechanisms to stabilize extra spatial dimensions in a new approach to the hierarchy problem, linking it to the cosmological constant problem and proposing solutions involving bulk cosmological constants, gauge fields, and brane arrangements.

Contribution

It introduces novel stabilization mechanisms for extra dimensions in a hierarchy problem framework without low energy supersymmetry or technicolor.

Findings

Positive bulk cosmological constant can prevent expansion of extra dimensions.

Supersymmetry breaking on the brane stabilizes against radiative corrections.

Large quantum numbers or brane lattices can prevent collapse of extra dimensions.

Abstract

A new framework for solving the hierarchy problem was recently proposed which does not rely on low energy supersymmetry or technicolor. The fundamental Planck mass is at a $\tev$ and the observed weakness of gravity at long distances is due the existence of new sub-millimeter spatial dimensions. In this picture the standard model fields are localized to a $(3+1)$-dimensional wall or ``3-brane''. The hierarchy problem becomes isomorphic to the problem of the largeness of the extra dimensions. This is in turn inextricably linked to the cosmological constant problem, suggesting the possibility of a common solution. The radii of the extra dimensions must be prevented from both expanding to too great a size, and collapsing to the fundamental Planck length $\tev^{-1}$. In this paper we propose a number of mechanisms addressing this question. We argue that a positive bulk cosmological constant $\bar\Lambda$ can stabilize the internal manifold against expansion, and that the value of $\bar\Lambda$ is not unstable to radiative corrections provided that the supersymmetries of string theory are broken by dynamics on our 3-brane. We further argue that the extra dimensions can be stabilized against collapse in a phenomenologically successful way by either of two methods: 1) Large, topologically conserved quantum numbers associated with higher-form bulk U(1) gauge fields, such as the naturally occurring Ramond-Ramond gauge fields, or the winding number of bulk scalar fields. 2) The brane-lattice-crystallization of a large number of 3-branes in the bulk. These mechanisms are consistent with theoretical, laboratory, and cosmological considerations such as the absence of large time variations in Newton's constant during and after primordial nucleosynthesis, and millimeter-scale tests of gravity.