Rotating strings and anomalous dimensions in Non-AdS holography

Abstract

In this paper we consider certain rigidly rotating closed string configurations in an asymptotically non-AdS string background. The string background is a deformation of AdS3 × M7. It interpolates between AdS3 and asymptotically linear dilaton I\!R × S1 × I\!R spacetime (times the internal compact manifold M7). We compute the quantity E - J (in the large J limit) where E is the energy and J is the angular momentum of the spinning strings. In the two dimensional CFT dual to string theory on AdS3 (times M7) it gives the anomalous dimensions of certain twist two and higher operators. We show in the deformed background that E - J is bounded. At a special value of the deformation coupling we also show that for spinning closed strings containing n > 2 cusps or spikes both E and J are bounded. In the CFT dual to string theory on AdS3 (times M7) the spinning cusped strings describe operators with twist n larger than two. In general, at other values of the deformation coupling, we demonstrate that this feature is exhibited only by those cusped strings with n > n0 where n0 is determined only by the deformation coupling. We also give simple exact Regge relations between E and J. We also study the closely related cusp anomalous dimension of a light-like Wilson loop. We comment on what E - J measures away from the CFT along the deformation in the coupling space. In the long string sector the deformation is dual to a single trace T T deformed orbifold theory. We determine the associated deformed sinh-Gordon model that classically describes the (long) strings near the boundary. This provides an example of single trace T T deformation in non-orbifold theories.

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