Hong Liu scite author profile

We consider the time evolution of entanglement entropy after a global quench in a strongly coupled holographic system, whose subsequent equilibration is described in the gravity dual by the gravitational collapse of a thin shell of matter resulting in a black hole. In the limit of large regions of entanglement, the evolution of entanglement entropy is controlled by the geometry around and inside the event horizon of the black hole, resulting in regimes of pre-local-equilibration quadratic growth (in time), post-local-equilibration linear growth, a late-time regime in which the evolution does not carry memory of the size and shape of the entangled region, and a saturation regime with critical behavior resembling those in continuous phase transitions. Collectively, these regimes suggest a picture of entanglement growth in which an "entanglement tsunami" carries entanglement inward from the boundary. We also make a conjecture on the maximal rate of entanglement growth in relativistic systems.

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Effective field theory of dissipative fluids

Crossley¹,

Glorioso²,

Liu³

2015

Preprint

207

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An extensive study on Raman spectra of water from 253 to 753 K at 30 MPa: A new insight into structure of water

Lü

et al. 2013

Journal of Molecular Spectroscopy

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Network domain structure in phase-separating polymer solutions

Liu

Bhattacharya

Chakrabarti

1999

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The Soret effect in dilute polymer solutions: Influence of chain length, chain stiffness, and solvent quality Results from molecular dynamics simulations of phase separation in a quenched polymer solution are presented for both two-and three-dimensional systems. Simulations clearly demonstrate the existence of a networklike pattern formation at an early to intermediate time regime for sufficiently dense polymer solutions. This network structure, however, relaxes at late times as the minimization of the interface energy wins over the elastic stress of the network. A crossover of domain growth exponent from a smaller value at intermediate times to the Lifshitz-Slyozov value of 1/3 at late times is seen in three-dimensional ͑3D͒ simulations of network breakup. Our results for the late-time growth exponent and dynamical scaling of the structure factors strongly indicate that the late-time growth kinetics of quenched polymer solutions belong to the same universality class of small molecular mixtures.

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Pulse-opencircuit voltammetry: A novel method characterizes bioanode performance from microbe-electrode interfacial processes

Yin

Lu²,

Song³

et al. 2022

Biosensors and Bioelectronics

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Hong Liu

Entanglement Tsunami: Universal Scaling in Holographic Thermalization

Effective field theory of dissipative fluids

An extensive study on Raman spectra of water from 253 to 753 K at 30 MPa: A new insight into structure of water

Network domain structure in phase-separating polymer solutions

Pulse-opencircuit voltammetry: A novel method characterizes bioanode performance from microbe-electrode interfacial processes

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