Measuring holographic entanglement entropy on a quantum simulator

Journal article


Publication Details

Author(s): Li K, Han M, Qu D, Huang Z, Long G, Wan Y, Lu D, Zeng B, Laflamme R
Journal: npj Quantum Information
Publication year: 2019
Volume: 5
ISSN: 2056-6387


Abstract

Quantum simulation promises to have wide applications in many fields where problems are hard to model with classical computers. Various quantum devices of different platforms have been built to tackle the problems in, say, quantum chemistry, condensed matter physics, and high-energy physics. Here, we report an experiment towards the simulation of quantum gravity by simulating the holographic entanglement entropy. On a six-qubit nuclear magnetic resonance quantum simulator, we demonstrate a key result of Anti-de Sitter/conformal field theory (AdS/CFT) correspondence-the Ryu-Takayanagi formula is demonstrated by measuring the relevant entanglement entropies on the perfect tensor state. The fidelity of our experimentally prepared the six-qubit state is 85.0% via full state tomography and reaches 93.7% if the signal-decay due to decoherence is taken into account. Our experiment serves as the basic module of simulating more complex tensor network states that exploring AdS/CFT correspondence. As the initial experimental attempt to study AdS/CFT via quantum information processing, our work opens up new avenues exploring quantum gravity phenomena on quantum simulators.


FAU Authors / FAU Editors

Han, Muxin Dr.
Chair for Theoretical Physics III (Quantum Gravity)


External institutions with authors

Florida Atlantic University
Southern University of Science and Technology
Tsinghua University
University of Waterloo (UW)


How to cite

APA:
Li, K., Han, M., Qu, D., Huang, Z., Long, G., Wan, Y.,... Laflamme, R. (2019). Measuring holographic entanglement entropy on a quantum simulator. npj Quantum Information, 5. https://dx.doi.org/10.1038/s41534-019-0145-z

MLA:
Li, Keren, et al. "Measuring holographic entanglement entropy on a quantum simulator." npj Quantum Information 5 (2019).

BibTeX: 

Last updated on 2019-23-05 at 14:38