Visualizing quantum phase transitions in the XXZ model via the quantum steering ellipsoid

• URL: http://arxiv.org/abs/2107.09839v1
• Date: Wed, 21 Jul 2021 02:14:21 GMT
• Title: Visualizing quantum phase transitions in the XXZ model via the quantum steering ellipsoid
• Authors: Ming-Ming Du, Da-Jian Zhang, Zhao-Yi Zhou, D. M. Tong
• Abstract summary: We show how entanglement measures whose nonanalyticities at critical points were tied to QPTs can be revealed through the quantum steering ellipsoid. We find that the QSE associated with the XXZ model changes in shape with the QPTs, that is, it is a needle in the ferromagnetic phase, an oblate spheroid in the gapless phase, and a prolate spheroid in the antiferromagnetic phase.
• Score: 0.0
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: The past two decades have witnessed a surge of interest in borrowing tools from quantum information theory to investigate quantum phase transitions (QPTs). The best known examples are entanglement measures whose nonanalyticities at critical points were tied to QPTs in a plethora of physical models. Here, focusing on the XXZ model, we show how QPTs can be revealed through the quantum steering ellipsoid (QSE), which is a geometric tool capable of characterizing both the strength and type of quantum correlations between two subsystems of a compound system. We find that the QSE associated with the XXZ model changes in shape with the QPTs, that is, it is a needle in the ferromagnetic phase, an oblate spheroid in the gapless phase, and a prolate spheroid in the antiferromagnetic phase. This finding offers an example demonstrating the intriguing possibility of unveiling QPTs in a geometrically visible fashion. Some connections between our results and previous ones are discussed.

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