Complexity of mixed Gaussian states from Fisher information geometry

112

We examine holographic complexity in the doubly holographic model introduced in [1, 2] to study quantum extremal islands. We focus on the holographic complexity=volume (CV) proposal for boundary subregions in the island phase. Exploiting the Fefferman-Graham expansion of the metric and other geometric quantities near the brane, we derive the leading contributions to the complexity and interpret these in terms of the generalized volume of the island derived from the induced higher-curvature gravity action on the brane. Motivated by these results, we propose a generalization of the CV proposal for higher curvature theories of gravity. Further, we provide two consistency checks of our proposal by studying Gauss-Bonnet gravity and f(ℛ) gravity in the bulk.

Section: Jhep02(2021)173mentioning

confidence: 99%

Quantum extremal islands made easy. Part III. Complexity on the brane

Hernandez

Myers

Ruan

2021

112

“…In order to understand the relation between entanglement and complexity, it is useful to study the optimal circuits and the corresponding circuit complexity when both the reference and the target states are mixed states [75][76][77][78][79]. The approach to the complexity of mixed states based on the purification complexity [75,76,79] is general, but evaluating JHEP05(2021)022 this quantity for large systems is technically complicated.…”

Section: Introductionmentioning

confidence: 99%

“…Some explicit results for large systems can be found by restricting to the simple case of bosonic Gaussian states and by employing the methods of the information geometry [80][81][82]. In our analysis we adopt the approach to the complexity of mixed states based on the Fisher information geometry [77], which allows to study large systems numerically. The crucial assumption underlying this approach is that all the states involved in the construction of the circuit are Gaussian.…”

Section: Introductionmentioning

confidence: 99%

Subsystem complexity after a global quantum quench

Giulio

Tonni

2021

Self Cite

We study the temporal evolution of the circuit complexity for a subsystem in harmonic lattices after a global quantum quench of the mass parameter, choosing the initial reduced density matrix as the reference state. Upper and lower bounds are derived for the temporal evolution of the complexity for the entire system. The subsystem complexity is evaluated by employing the Fisher information geometry for the covariance matrices. We discuss numerical results for the temporal evolutions of the subsystem complexity for a block of consecutive sites in harmonic chains with either periodic or Dirichlet boundary conditions, comparing them with the temporal evolutions of the entanglement entropy. For infinite harmonic chains, the asymptotic value of the subsystem complexity is studied through the generalised Gibbs ensemble.

“…which is nothing but Uhlmann's fidelity (2.7). We also note the maximization condition also implies the two purifications are connected by the geometric mean (see [54] for more discussion about its application to the complexity of Gaussian states), i.e.,…”

Section: Bures Distance and Bures Metricmentioning

confidence: 99%

“…Different from the purification complexity defined in(2.20), the authors in[54] develop a direct way to calculate the complexity for arbitrary Gaussian states with taking the Fisher-Rao metric as the complexity measure.…”

mentioning

confidence: 99%

Purification complexity without purifications

Ruan

2021

We generalize the Fubini-Study method for pure-state complexity to generic quantum states by taking Bures metric or quantum Fisher information metric (QFIM) on the space of density matrices as the complexity measure. Due to Uhlmann’s theorem, we show that the mixed-state complexity exactly equals the purification complexity measured by the Fubini-Study metric for purified states but without explicitly applying any purification. We also find the purification complexity is non-increasing under any trace-preserving quantum operations. We also study the mixed Gaussian states as an example to explicitly illustrate our conclusions for purification complexity.