Time-Dependent Integrability from Gauge Theory, I
Abstract
Solvable time-dependent systems provide important settings for studying non-equilibrium physics, where exact results are rare.
They are also useful for benchmarking quantum simulations, which can directly probe real-time dynamics beyond the reach of conventional numerical approaches.
In this paper, we show that the four-dimensional Chern-Simons theory offers a natural and unifying framework for constructing such systems.
Focusing on classically integrable field theories, we consider a generalization of the four-dimensional Chern-Simons theory in which the usual holomorphic one-form is replaced by a more general, spacetime-dependent one-form.
This yields a systematic procedure for generating time-dependent integrable field theories and establishes a universal relation: for every theory obtained in this way, the allowed time dependence coincides with the one-loop renormalization group flow.
Despite the explicit time dependence, these theories retain Lax integrability and remain solvable by inverse scattering methods.
Our construction applies to both ultralocal and non-ultralocal theories and extends previously known time-dependent sigma models to a much broader class of integrable systems.
It also admits rewriting as dilaton gravity coupled to matter, producing a large family of classically integrable dilaton gravity theories in two dimensions.
We also comment on connections to time-dependent integrable models studied recently in condensed matter physics and non-autonomous integrable systems arising from dimensionally-reduced Einstein gravity.
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