Abstract
We consider operator growth for generic large-N gauge theories at finite temperature. Our analysis is performed in terms of Fourier modes, which do not mix with other operators as time evolves, and whose correlation functions are determined by their two-point functions alone, at leading order in the large-N limit. The algebra of these modes allows for a simple analysis of the operators with whom the initial operator mixes over time, and guarantees the existence of boundary CFT operators closing the bulk Poincaré algebra, describing the experience of infalling observers. We discuss several existing approaches to operator growth, such as number operators, proper energies, the many-body recursion method, quantum circuit complexity, and comment on its relation to classical chaos in black hole dynamics. The analysis evades the bulk vs boundary dichotomy and shows that all such approaches are the same at both sides of the holographic duality, a statement that simply rests on the equality between operator evolution itself. In the way, we show all these approaches have a natural formulation in terms of the Gelfand-Naimark-Segal (GNS) construction, which maps operator evolution to a more conventional quantum state evolution, and provides an extension of the notion of operator growth to QFT.
Highlights
The structure of the Heisenberg’s time evolution in chaotic systems has attracted some recent interest for several reasons
The algebra of these modes allows for a simple analysis of the operators with whom the initial operator mixes over time, and guarantees the existence of boundary CFT operators closing the bulk Poincare algebra, describing the experience of infalling observers
One gets exponential growths with faster rates. This statement seems similar to the results found in [47] for out-of-time-ordered correlation functions, which show that different choices of euclidean separations in the OTOC 4-pt function might lead to faster growth than the chaos bound [8]
Summary
Controlling the Heisenberg time evolution (1.2) in generic large-N gauge theories for a subset of initial operators O for whom large-N factorization of correlation functions holds [23]. Hypothesis (ETH) [32], the set of states in the Hilbert space where the previous correlation functions hold is much larger This is because ETH ensures the same expectation values apply to most energy eigenstates compatible with the physical temperature. Proceeding as before, we can Fourier transform the fields, but against modular time evolution This allows for a simple computation of the action of Onmod in all eigenstates of the theory, in the vein of (2.4), if the correlators of the modular field modes are gaussian, as expected for holographic theories with free bulk duals
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