Liouville action as path-integral complexity: from continuous tensor networks to AdS/CFT

Caputa, Paweł; Kundu, Nilay; Miyaji, Masamichi; Takayanagi, Tadashi; Watanabe, Kento

doi:10.1007/jhep11(2017)097

Cited by 281 publications

(415 citation statements)

References 90 publications

(184 reference statements)

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“…Interesting questions for the future include generalizing this approach to higher dimensions; understanding subregion complexity using the optimization approach of []; relating our approach with the holographic renormalization properties of the different proposals for complexity; and studying subregion complexity in time‐dependent systems …”

Section: Discussionmentioning

confidence: 99%

“…Interesting questions for the future include generalizing this approach to higher dimensions; understanding subregion complexity using the optimization approach of [38,[46][47][48]; relating our approach with the holographic renormalization properties of the different proposals for complexity; [11,49] and studying subregion complexity in time-dependent systems. [12] Turning to tensor network states, we proposed that their subregion complexity should be understood as the number of local tensors required to build the map embedding the the Hilbert space cut by the RT surface in the Hilbert space of the entangling region A.…”

Section: Discussionmentioning

confidence: 99%

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Topological Complexity in AdS₃/CFT₂

Abt

Erdmenger

Hinrichsen

et al. 2018

Fortschritte der Physik

105

123

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We consider subregion complexity within the AdS3/CFT2 correspondence. We rewrite the volume proposal, according to which the complexity of a reduced density matrix is given by the spacetime volume contained inside the associated Ryu‐Takayanagi (RT) surface, in terms of an integral over the curvature. Using the Gauss‐Bonnet theorem we evaluate this quantity for general entangling regions and temperature. In particular, we find that the discontinuity that occurs under a change in the RT surface is given by a fixed topological contribution, independent of the temperature or details of the entangling region. We offer a definition and interpretation of subregion complexity in the context of tensor networks, and show numerically that it reproduces the qualitative features of the holographic computation in the case of a random tensor network using its relation to the Ising model. Finally, we give a prescription for computing subregion complexity directly in CFT using the kinematic space formalism, and use it to reproduce some of our explicit gravity results obtained at zero temperature. We thus obtain a concrete matching of results for subregion complexity between the gravity and tensor network approaches, as well as a CFT prescription.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Topological Complexity in AdS₃/CFT₂

Abt

Erdmenger

Hinrichsen

et al. 2018

Fortschritte der Physik

105

123

View full text Add to dashboard Cite

show abstract

“…Ultimately, one would like to establish a concrete translation of the new observables in the bulk to a specific quantity in the boundary theory, but this probably requires new insights into how complexity can be formulated in quantum field theories. Some interesting progress in this direction can be found in [39][40][41].…”

Section: Jhep06(2018)046mentioning

confidence: 98%

Holographic complexity in Vaidya spacetimes. Part I

Chapman

Marrochio

Myers

2018

J. High Energ. Phys.

150

222

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We examine holographic complexity in time-dependent Vaidya spacetimes with both the complexity=volume (CV) and complexity=action (CA) proposals. We focus on the evolution of the holographic complexity for a thin shell of null fluid, which collapses into empty AdS space and forms a (one-sided) black hole. In order to apply the CA approach, we introduce an action principle for the null fluid which sources the Vaidya geometries, and we carefully examine the contribution of the null shell to the action. Further, we find that adding a particular counterterm on the null boundaries of the Wheeler-DeWitt patch is essential if the gravitational action is to properly describe the complexity of the boundary state. For both the CV proposal and the CA proposal (with the extra boundary counterterm), the late time limit of the growth rate of the holographic complexity for the one-sided black hole is precisely the same as that found for an eternal black hole.

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“…More precisely, we will define a gate to act simply on the state |ψ if ψ|G i |ψ ∼ 1−O( ), where is the tolerance. 4 Although this definition is slightly outside the original framework described in [38], it is nevertheless in harmony with recent attempts to represent a quantum circuit by taking the continuum limit of the tensor network preparing the state [43]. From the tensor network perspective, each node in the network contributes a gate like e vO , where O is a hermitian operator and 'v' is roughly the infinitesimal volume associated with the gate.…”

Section: Defining Complexitymentioning

confidence: 87%

Complexity is simple!

Cottrell

2018

J. High Energ. Phys.

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In this note we investigate the role of Lloyd's computational bound in holographic complexity. Our goal is to translate the assumptions behind Lloyd's proof into the bulk language. In particular, we discuss the distinction between orthogonalizing and 'simple' gates and argue that these notions are useful for diagnosing holographic complexity. We show that large black holes constructed from series circuits necessarily employ simple gates, and thus do not satisfy Lloyd's assumptions. We also estimate the degree of parallel processing required in this case for elementary gates to orthogonalize. Finally, we show that for small black holes at fixed chemical potential, the orthogonalization condition is satisfied near the phase transition, supporting a possible argument for the Weak Gravity Conjecture first advocated in [1].

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Liouville action as path-integral complexity: from continuous tensor networks to AdS/CFT

Cited by 281 publications

References 90 publications

Topological Complexity in AdS₃/CFT₂

Topological Complexity in AdS₃/CFT₂

Holographic complexity in Vaidya spacetimes. Part I

Complexity is simple!

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Liouville action as path-integral complexity: from continuous tensor networks to AdS/CFT

Cited by 281 publications

References 90 publications

Topological Complexity in AdS3/CFT2

Topological Complexity in AdS3/CFT2

Holographic complexity in Vaidya spacetimes. Part I

Complexity is simple!

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Topological Complexity in AdS₃/CFT₂

Topological Complexity in AdS₃/CFT₂