Density-wave steady-state phase of dissipative ultracold fermions with nearest-neighbor interactions

Jaromir Panas; Michael Pasek; Arya Dhar; Tao Qin; Andreas Geißler; Mohsen Hafez-Torbati; Max E. Sorantin; Irakli Titvinidze; Walter Hofstetter

doi:10.1103/PhysRevB.99.115125

Density-wave steady-state phase of dissipative ultracold fermions with nearest-neighbor interactions

Jaromir Panas, Michael Pasek, Arya Dhar, Tao Qin, Andreas Geißler, Mohsen Hafez-Torbati, Max E. Sorantin, Irakli Titvinidze, Walter Hofstetter

Institute of Theoretical and Computational Physics (5150)

Research output: Contribution to journal › Article › peer-review

Abstract

In this work, we investigate the effect of local dissipation on the presence of density-wave ordering in spinful fermions with both local and nearest-neighbor interactions as described by the extended Hubbard model. We find density-wave order to be robust against decoherence effects up to a critical point where the system becomes homogeneous with no spatial ordering. Our results will be relevant for future cold-atom experiments using fermions with nonlocal interactions arising from the dressing by highly excited Rydberg states, which have finite lifetimes due to spontaneous emission processes.

Original language	English
Article number	115125
Journal	Physical Review B
Volume	99
Issue number	11
DOIs	https://doi.org/10.1103/PhysRevB.99.115125
Publication status	Published - 18 Mar 2019

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics

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10.1103/PhysRevB.99.115125

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abstract = "In this work, we investigate the effect of local dissipation on the presence of density-wave ordering in spinful fermions with both local and nearest-neighbor interactions as described by the extended Hubbard model. We find density-wave order to be robust against decoherence effects up to a critical point where the system becomes homogeneous with no spatial ordering. Our results will be relevant for future cold-atom experiments using fermions with nonlocal interactions arising from the dressing by highly excited Rydberg states, which have finite lifetimes due to spontaneous emission processes.",

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AU - Panas, Jaromir

AU - Pasek, Michael

AU - Dhar, Arya

AU - Qin, Tao

AU - Geißler, Andreas

AU - Hafez-Torbati, Mohsen

AU - Sorantin, Max E.

AU - Titvinidze, Irakli

AU - Hofstetter, Walter

PY - 2019/3/18

Y1 - 2019/3/18

N2 - In this work, we investigate the effect of local dissipation on the presence of density-wave ordering in spinful fermions with both local and nearest-neighbor interactions as described by the extended Hubbard model. We find density-wave order to be robust against decoherence effects up to a critical point where the system becomes homogeneous with no spatial ordering. Our results will be relevant for future cold-atom experiments using fermions with nonlocal interactions arising from the dressing by highly excited Rydberg states, which have finite lifetimes due to spontaneous emission processes.

AB - In this work, we investigate the effect of local dissipation on the presence of density-wave ordering in spinful fermions with both local and nearest-neighbor interactions as described by the extended Hubbard model. We find density-wave order to be robust against decoherence effects up to a critical point where the system becomes homogeneous with no spatial ordering. Our results will be relevant for future cold-atom experiments using fermions with nonlocal interactions arising from the dressing by highly excited Rydberg states, which have finite lifetimes due to spontaneous emission processes.

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Density-wave steady-state phase of dissipative ultracold fermions with nearest-neighbor interactions

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