Closed strings in Misner space: stringy fuzziness with a twist

Misner space, also known as the Lorentzian orbifold , is the simplest tree-level solution of string theory with a cosmological singularity. We compute tree-level scattering amplitudes involving twisted states, using operator and current algebra techniques. We find that, due to zero-point quantum fluctuations of the excited modes, twisted strings with a large winding number w are fuzzy on a scale , which can be much larger than the string scale. Wavefunctions are smeared by an operator reminiscent of the Moyal product of non-commutative geometry, which, since Δ(ν) is real, modulates the amplitude rather than the phase of the wavefunction, and is purely gravitational in its origin. We compute the scattering amplitude of two twisted states and one tachyon or graviton, and find a finite result. The scattering amplitude of two twisted and two untwisted states is found to diverge, due to the propagation of intermediate winding strings with vanishing boost momentum. The scattering amplitude of three twisted fields is computed by analytic continuation from three-point amplitudes of states with non-zero p+ in the Nappi–Witten plane wave, and the non-locality of the three-point vertex is found to diverge for certain kinematical configurations. Our results for the three-point amplitudes allow us in principle to compute, to leading order, the back-reaction on the metric due to a condensation of coherent winding strings.