Schmiedmayer, Hannes-Jörg

2023-11-09T06:36:33Z

2023-11-09T06:36:33Z

2023-10-10

<div class="csl-bib-body"> <div class="csl-entry">Schmiedmayer, H.-J. (2023, October 10). <i>Quantum Field Theories in the Lab</i> [Conference Presentation]. QuFiCh Workshop: Brainstorm on Intersections between Quantum Fields and Quantum Chemistry, Luxemburg, Luxembourg.</div> </div>

http://hdl.handle.net/20.500.12708/189520

I discuss a different, by which the a Quantum Field Theory to quantum simulate emerges naturally from a completely different microscopic Hamiltonian. I will illustrate this in the example of the emergence of the Sine-Gordon quantum field theory from the microscopic description of two tunnel coupled super fluids [1]. Special emphasis will be put on how to verify such emergent quantum simulators and how to characterize them. Thereby I will present different tools: High order correlation functions and their factorization [1], the evaluation of the quantum effective action and the momentum dependence of propagators and vertices (running couplings, renormalization of mass etc ..) of the emerging quantum field theory [2] and quantum field tomography that points to a new way to read out quantum simulators [3] and our path to directly learn the quantum simulated Hamiltonian from the experimental data. Together they establish general methods to analyse quantum systems through experiments and thus represents a crucial ingredient towards the implementation and verification of emerging quantum simulators. As an example, I will report on measuring area laws of mutual information [4] in a quantum simulation of the Klein-Gordon model.

I discuss a different, by which the a Quantum Field Theory to quantum simulate emerges naturally from a completely different microscopic Hamiltonian. I will illustrate this in the example of the emergence of the Sine-Gordon quantum field theory from the microscopic description of two tunnel coupled super fluids [1]. Special emphasis will be put on how to verify such emergent quantum simulators and how to characterize them. Thereby I will present different tools: High order correlation functions and their factorization [1], the evaluation of the quantum effective action and the momentum dependence of propagators and vertices (running couplings, renormalization of mass etc ..) of the emerging quantum field theory [2] and quantum field tomography that points to a new way to read out quantum simulators [3] and our path to directly learn the quantum simulated Hamiltonian from the experimental data. Together they establish general methods to analyse quantum systems through experiments and thus represents a crucial ingredient towards the implementation and verification of emerging quantum simulators. As an example, I will report on measuring area laws of mutual information [4] in a quantum simulation of the Klein-Gordon model.

en

quantum field theory

Quantum Field Theories in the Lab

Presentation

Vortrag

Conference Presentation

invited

Q3

Quantum Modeling and Simulation

100

https://qufich.github.io/?trk=public_post-text

E141-02 - Forschungsbereich Atom Physics and Quantum Optics

QuFiCh Workshop: Brainstorm on Intersections between Quantum Fields and Quantum Chemistry

09-10-2023

11-10-2023

On Site

Event for scientific audience

Luxemburg

LU

Schmiedmayer, Hannes-Jörg

Physik, Astronomie

1030

100

en

restricted

Publications

conference paper not in proceedings

http://purl.org/coar/resource_type/c_18cp

no Fulltext

E141-02 - Forschungsbereich Atom Physics and Quantum Optics

E141 - Atominstitut