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Autori principali: Zeng, Yihang, Sun, Dihao, Zhang, Naiyuan J., Nguyen, Ron Q., Shi, Qianhui, Okounkova, A., Watanabe, K., Taniguchi, T., Hone, J., Dean, C. R., Li, J. I. A.
Natura: Preprint
Pubblicazione: 2023
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Accesso online:https://arxiv.org/abs/2306.16995
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author Zeng, Yihang
Sun, Dihao
Zhang, Naiyuan J.
Nguyen, Ron Q.
Shi, Qianhui
Okounkova, A.
Watanabe, K.
Taniguchi, T.
Hone, J.
Dean, C. R.
Li, J. I. A.
author_facet Zeng, Yihang
Sun, Dihao
Zhang, Naiyuan J.
Nguyen, Ron Q.
Shi, Qianhui
Okounkova, A.
Watanabe, K.
Taniguchi, T.
Hone, J.
Dean, C. R.
Li, J. I. A.
contents One of the most spectacular properties associated with Bose-Einstein condensation (BEC) is superfluidity in which the system exhibits zero viscosity and flows without dissipation. The superfluid phase has been observed in wide ranging Bosonic systems spanning naturally occurring quantum fluids, such as liquid helium, to engineered platforms such as bilayer excitons and cold atom systems. Theoretical works have proposed that interactions could drive the BEC ground state into another exotic phase that simultaneously exhibits properties of both a crystalline solid and a superfluid - termed a supersolid. Identifying a material system, however, that hosts the predicted BEC solid phase, driven purely by interactions and without imposing an external lattice potential, has remained elusive. Here we report observation of a superfluid to insulator transition in the layer-imbalanced regime of bilayer magneto-excitons. Mapping the transport behavior of the bilayer condensate as a function of density and temperature, suggests that the insulating phase is an ordered state of dilute excitons, stabilized by dipole interactions. The insulator melts into a recovered superfluid upon increasing the temperature, which could indicate that the low temperature solid is also a quantum coherent phase.
format Preprint
id arxiv_https___arxiv_org_abs_2306_16995
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Evidence for a Superfluid-to-solid Transition of Bilayer Excitons
Zeng, Yihang
Sun, Dihao
Zhang, Naiyuan J.
Nguyen, Ron Q.
Shi, Qianhui
Okounkova, A.
Watanabe, K.
Taniguchi, T.
Hone, J.
Dean, C. R.
Li, J. I. A.
Mesoscale and Nanoscale Physics
One of the most spectacular properties associated with Bose-Einstein condensation (BEC) is superfluidity in which the system exhibits zero viscosity and flows without dissipation. The superfluid phase has been observed in wide ranging Bosonic systems spanning naturally occurring quantum fluids, such as liquid helium, to engineered platforms such as bilayer excitons and cold atom systems. Theoretical works have proposed that interactions could drive the BEC ground state into another exotic phase that simultaneously exhibits properties of both a crystalline solid and a superfluid - termed a supersolid. Identifying a material system, however, that hosts the predicted BEC solid phase, driven purely by interactions and without imposing an external lattice potential, has remained elusive. Here we report observation of a superfluid to insulator transition in the layer-imbalanced regime of bilayer magneto-excitons. Mapping the transport behavior of the bilayer condensate as a function of density and temperature, suggests that the insulating phase is an ordered state of dilute excitons, stabilized by dipole interactions. The insulator melts into a recovered superfluid upon increasing the temperature, which could indicate that the low temperature solid is also a quantum coherent phase.
title Evidence for a Superfluid-to-solid Transition of Bilayer Excitons
topic Mesoscale and Nanoscale Physics
url https://arxiv.org/abs/2306.16995