Volume 4, Issue 2
Effects of Disorder on Quantum Correlation of Ultracold Bose Gases Released from a Two-Dimensional Optical Lattice

Yan Li & Nao-Sheng Qiao

J. At. Mol. Sci., 4 (2013), pp. 155-168.

Published online: 2013-04

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  • Abstract

High-order quantum correlation provides powerful methods to reveal the quantum many-body behavior of ultracold atomic gases. In this work, the second-order quantum correlation is adopted to study the many-body behavior of ultracold Bose gases in the presence of both a two-dimensional optical lattice and weak disorder. According to investigations, it is found that even a weak disorder plays a significant role in the quantum many-body behavior, which manifests itself through the second-order quantum correlation. With the Bogoliubov theory, our studies show that both interatomic interactions and weak disorder would destroy the first-order quantum coherence of the condensate because of the depletion, and the resulting depletion has significant characteristic in the second-order correlation of the system.  

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COPYRIGHT: © Global Science Press

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liyan_2001@126.com (Yan Li)

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@Article{JAMS-4-155, author = {Li , Yan and Qiao , Nao-Sheng}, title = {Effects of Disorder on Quantum Correlation of Ultracold Bose Gases Released from a Two-Dimensional Optical Lattice}, journal = {Journal of Atomic and Molecular Sciences}, year = {2013}, volume = {4}, number = {2}, pages = {155--168}, abstract = {

High-order quantum correlation provides powerful methods to reveal the quantum many-body behavior of ultracold atomic gases. In this work, the second-order quantum correlation is adopted to study the many-body behavior of ultracold Bose gases in the presence of both a two-dimensional optical lattice and weak disorder. According to investigations, it is found that even a weak disorder plays a significant role in the quantum many-body behavior, which manifests itself through the second-order quantum correlation. With the Bogoliubov theory, our studies show that both interatomic interactions and weak disorder would destroy the first-order quantum coherence of the condensate because of the depletion, and the resulting depletion has significant characteristic in the second-order correlation of the system.  

}, issn = {2079-7346}, doi = {https://doi.org/10.4208/jams.051412.060612a}, url = {http://global-sci.org/intro/article_detail/jams/8244.html} }
TY - JOUR T1 - Effects of Disorder on Quantum Correlation of Ultracold Bose Gases Released from a Two-Dimensional Optical Lattice AU - Li , Yan AU - Qiao , Nao-Sheng JO - Journal of Atomic and Molecular Sciences VL - 2 SP - 155 EP - 168 PY - 2013 DA - 2013/04 SN - 4 DO - http://doi.org/10.4208/jams.051412.060612a UR - https://global-sci.org/intro/article_detail/jams/8244.html KW - disorder, second-order correlation, ultracold atomic gases, optical lattice. AB -

High-order quantum correlation provides powerful methods to reveal the quantum many-body behavior of ultracold atomic gases. In this work, the second-order quantum correlation is adopted to study the many-body behavior of ultracold Bose gases in the presence of both a two-dimensional optical lattice and weak disorder. According to investigations, it is found that even a weak disorder plays a significant role in the quantum many-body behavior, which manifests itself through the second-order quantum correlation. With the Bogoliubov theory, our studies show that both interatomic interactions and weak disorder would destroy the first-order quantum coherence of the condensate because of the depletion, and the resulting depletion has significant characteristic in the second-order correlation of the system.  

Yan Li & Nao-Sheng Qiao. (2020). Effects of Disorder on Quantum Correlation of Ultracold Bose Gases Released from a Two-Dimensional Optical Lattice. Journal of Atomic and Molecular Sciences. 4 (2). 155-168. doi:10.4208/jams.051412.060612a
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