English

Metastring Theory and Modular Space-time

High Energy Physics - Theory 2015-03-02 v1

Abstract

String theory is canonically accompanied with a space-time interpretation which determines S-matrix-like observables, and connects to the standard physics at low energies in the guise of local effective field theory. Recently, we have introduced a reformulation of string theory which does not rely on an {\it a priori} space-time interpretation or a pre-assumption of locality. This \hlt{metastring theory} is formulated in such a way that stringy symmetries (such as T-duality) are realized linearly. In this paper, we study metastring theory on a flat background and develop a variety of technical and interpretational ideas. These include a formulation of the moduli space of Lorentzian worldsheets, a careful study of the symplectic structure and consequently consistent closed and open boundary conditions, and the string spectrum and operator algebra. What emerges from these studies is a new quantum notion of space-time that we refer to as a quantum Lagrangian or equivalently a \hlt{modular space-time}. This concept embodies the standard tenets of quantum theory and implements in a precise way a notion of {relative locality}. The usual string backgrounds (non-compact space-time along with some toroidally compactified spatial directions) are obtained from modular space-time by a limiting procedure that can be thought of as a correspondence limit.

Keywords

Cite

@article{arxiv.1502.08005,
  title  = {Metastring Theory and Modular Space-time},
  author = {Laurent Freidel and Robert G. Leigh and Djordje Minic},
  journal= {arXiv preprint arXiv:1502.08005},
  year   = {2015}
}
R2 v1 2026-06-22T08:39:59.905Z