The quantum sine-Gordon model with quantum circuits
- URL: http://arxiv.org/abs/2007.06874v2
- Date: Wed, 26 May 2021 05:57:15 GMT
- Title: The quantum sine-Gordon model with quantum circuits
- Authors: Ananda Roy, Dirk Schuricht, Johannes Hauschild, Frank Pollmann, and
Hubert Saleur
- Abstract summary: We numerically investigate a one-dimensional, faithful, analog, quantum electronic circuit simulator built out of Josephson junctions.
We provide numerical evidence that the parameters required to realize the quantum sine-Gordon model are accessible with modern-day superconducting circuit technology.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Analog quantum simulation has the potential to be an indispensable technique
in the investigation of complex quantum systems. In this work, we numerically
investigate a one-dimensional, faithful, analog, quantum electronic circuit
simulator built out of Josephson junctions for one of the paradigmatic models
of an integrable quantum field theory: the quantum sine-Gordon (qSG) model in
1+1 space-time dimensions. We analyze the lattice model using the density
matrix renormalization group technique and benchmark our numerical results with
existing Bethe ansatz computations. Furthermore, we perform analytical
form-factor calculations for the two-point correlation function of vertex
operators, which closely agree with our numerical computations. Finally, we
compute the entanglement spectrum of the qSG model. We compare our results with
those obtained using the integrable lattice-regularization based on the quantum
XYZ chain and show that the quantum circuit model is less susceptible to
corrections to scaling compared to the XYZ chain. We provide numerical evidence
that the parameters required to realize the qSG model are accessible with
modern-day superconducting circuit technology, thus providing additional
credence towards the viability of the latter platform for simulating strongly
interacting quantum field theories.
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