Mechanisms for the emergence of Gaussian correlations
We comprehensively investigate two distinct mechanisms leading to memory loss of non-Gaussian correlations after switching off the interactions in an isolated quantum system undergoing out-of-equilibrium dynamics. The first mechanism is based on spatial scrambling and results in the emergence of loc...
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2023
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Science::Physics Gaussian Correlations Quantum Field Theories |
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Science::Physics Gaussian Correlations Quantum Field Theories Gluza, Marek Schweigler, Thomas Tajik, Mohammadamin Sabino, João Cataldini, Federica Møller, Frederik S. Ji, Si-Cong Rauer, Bernhard Schmiedmayer, Jörg Eisert, Jens Sotiriadis, Spyros Mechanisms for the emergence of Gaussian correlations |
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We comprehensively investigate two distinct mechanisms leading to memory loss of non-Gaussian correlations after switching off the interactions in an isolated quantum system undergoing out-of-equilibrium dynamics. The first mechanism is based on spatial scrambling and results in the emergence of locally Gaussian steady states in large systems evolving over long times. The second mechanism, characterized as 'canonical transmutation', is based on the mixing of a pair of canonically conjugate fields, one of which initially exhibits non-Gaussian fluctuations while the other is Gaussian and dominates the dynamics, resulting in the emergence of relative Gaussianity even at finite system sizes and times. We evaluate signatures of the occurrence of the two candidate mechanisms in a recent experiment that has observed Gaussification in an atom-chip controlled ultracold gas and elucidate evidence that it is canonical transmutation rather than spatial scrambling that is responsible for Gaussification in the experiment. Both mechanisms are shown to share the common feature that the Gaussian correlations revealed dynamically by the quench are already present though practically inaccessible at the initial time. On the way, we present novel observations based on the experimental data, demonstrating clustering of equilibrium correlations, analyzing the dynamics of full counting statistics, and utilizing tomographic reconstructions of quantum field states. Our work aims at providing an accessible presentation of the potential of atom-chip experiments to explore fundamental aspects of quantum field theories in quantum simulations. |
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School of Physical and Mathematical Sciences |
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School of Physical and Mathematical Sciences Gluza, Marek Schweigler, Thomas Tajik, Mohammadamin Sabino, João Cataldini, Federica Møller, Frederik S. Ji, Si-Cong Rauer, Bernhard Schmiedmayer, Jörg Eisert, Jens Sotiriadis, Spyros |
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Article |
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Gluza, Marek Schweigler, Thomas Tajik, Mohammadamin Sabino, João Cataldini, Federica Møller, Frederik S. Ji, Si-Cong Rauer, Bernhard Schmiedmayer, Jörg Eisert, Jens Sotiriadis, Spyros |
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Gluza, Marek |
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Mechanisms for the emergence of Gaussian correlations |
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Mechanisms for the emergence of Gaussian correlations |
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Mechanisms for the emergence of Gaussian correlations |
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Mechanisms for the emergence of Gaussian correlations |
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Mechanisms for the emergence of Gaussian correlations |
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mechanisms for the emergence of gaussian correlations |
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2023 |
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https://hdl.handle.net/10356/164227 |
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sg-ntu-dr.10356-1642272023-02-28T20:07:53Z Mechanisms for the emergence of Gaussian correlations Gluza, Marek Schweigler, Thomas Tajik, Mohammadamin Sabino, João Cataldini, Federica Møller, Frederik S. Ji, Si-Cong Rauer, Bernhard Schmiedmayer, Jörg Eisert, Jens Sotiriadis, Spyros School of Physical and Mathematical Sciences Science::Physics Gaussian Correlations Quantum Field Theories We comprehensively investigate two distinct mechanisms leading to memory loss of non-Gaussian correlations after switching off the interactions in an isolated quantum system undergoing out-of-equilibrium dynamics. The first mechanism is based on spatial scrambling and results in the emergence of locally Gaussian steady states in large systems evolving over long times. The second mechanism, characterized as 'canonical transmutation', is based on the mixing of a pair of canonically conjugate fields, one of which initially exhibits non-Gaussian fluctuations while the other is Gaussian and dominates the dynamics, resulting in the emergence of relative Gaussianity even at finite system sizes and times. We evaluate signatures of the occurrence of the two candidate mechanisms in a recent experiment that has observed Gaussification in an atom-chip controlled ultracold gas and elucidate evidence that it is canonical transmutation rather than spatial scrambling that is responsible for Gaussification in the experiment. Both mechanisms are shown to share the common feature that the Gaussian correlations revealed dynamically by the quench are already present though practically inaccessible at the initial time. On the way, we present novel observations based on the experimental data, demonstrating clustering of equilibrium correlations, analyzing the dynamics of full counting statistics, and utilizing tomographic reconstructions of quantum field states. Our work aims at providing an accessible presentation of the potential of atom-chip experiments to explore fundamental aspects of quantum field theories in quantum simulations. Published version Joint work at FU Berlin and TU Wien has been supported by the DFG (FOR 2724 on ‘Thermal machines in the quantum world’ and CRC 183) and the FQXi on ‘Fueling quantum field machines with information’, for which it constitutes important inter-node preparatory theoretical experimental work in the development of quantum field machines. FUB has also received funding from the European Union’s Horizon2020 research and innovation programme under grant agreement No. 817482 (PASQuanS) on programmable quantum simulators. This work touches also upon identifying platforms of programmable cold atomic quantum simulators, as being funded by BMBF (FermiQP), and on methods of verification of quantum simulators, as funded by the Munich Quantum Valley (K8). It has also been supported by the DFG/FWF Collaborative Research Centre ‘SFB 1225 (ISOQUANT)’ and the ESQ Discovery Grant ‘Emergence of physical laws: From mathematical foundations to applications in many body physics’ of the Austrian Academy of Sciences (ÖAW). F. C., F. S. M., B. R., J. Sabino and T. S. acknowledge support by the Austrian Science Fund (FWF) in the framework of the Doctoral School on Complex Quantum Systems (CoQuS). T. S. acknowledges support by the Max Kade Foundation through a postdoctoral fellowship. J. Sabino acknowledges support from Fundação para a Ciência e a Tecnologia (Portugal) through Project No. UIDB/EEA/50008/2020 and from the DP-PMI and FCT (Portugal). S. S. has been also supported by the Slovenian Research Agency (ARRS) under grant QTE (N1-0109) and by the ERC Advanced Grant OMNES (694544). J. E., M. G., J. Schmiedmayer and S. S. thank the Erwin Schrödinger Institute for its hospitality and support under the programme ‘Quantum Simulation–from Theory to Application’ (LCW 2019). 2023-01-10T06:12:27Z 2023-01-10T06:12:27Z 2022 Journal Article Gluza, M., Schweigler, T., Tajik, M., Sabino, J., Cataldini, F., Møller, F. S., Ji, S., Rauer, B., Schmiedmayer, J., Eisert, J. & Sotiriadis, S. (2022). Mechanisms for the emergence of Gaussian correlations. SciPost Physics, 12(3). https://dx.doi.org/10.21468/SCIPOSTPHYS.12.3.113 2542-4653 https://hdl.handle.net/10356/164227 10.21468/SCIPOSTPHYS.12.3.113 2-s2.0-85128983849 3 12 en SciPost Physics Copyright M. Gluza et al. This work is licensed under the Creative Commons Attribution 4.0 International License. Published by the SciPost Foundation. application/pdf |