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Quantum Algorithms
Collapse and Revival in Holographic Quenches
arXiv
Authors: Emilia da Silva, Esperanza Lopez, Javier Mas, Alexandre Serantes
Year
2014
Paper ID
45823
Status
Preprint
Abstract Read
~2 min
Abstract Words
162
Citations
N/A
Abstract
We study holographic models related to global quantum quenches in finite size systems. The holographic set up describes naturally a CFT, which we consider on a circle and a sphere. The enhanced symmetry of the conformal group on the circle motivates us to compare the evolution in both cases. Depending on the initial conditions, the dual geometry exhibits oscillations that we holographically interpret as revivals of the initial field theory state. On the sphere, this only happens when the energy density created by the quench is small compared to the system size. However on the circle considerably larger energy densities are compatible with revivals. Two different timescales emerge in this latter case. A collapse time, when the system appears to have dephased, and the revival time, when after rephasing the initial state is partially recovered. The ratio of these two times depends upon the initial conditions in a similar way to what is observed in some experimental setups exhibiting collapse and revivals.
Why This Paper Matters
- It adds a 2014 reference point for readers tracking recent quantum research.
- We study holographic models related to global quantum quenches in finite size systems.
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