Bipartite Current Fluctuations in Quantum Wires through Charge Fractionalization

• URL: http://arxiv.org/abs/2501.14410v1
• Date: Fri, 24 Jan 2025 11:22:21 GMT
• Title: Bipartite Current Fluctuations in Quantum Wires through Charge Fractionalization
• Authors: Magali Korolev, Karyn Le Hur,
• Abstract summary: We introduce a new method from the bipartite current fluctuations and the divergence theorem. They reveal the fractional charges related to ground-state energetics and the proximity to Mott physics in the same ballistic quantum wires. This also encodes the behavior of the electron Green's function in space.
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• Abstract: Quantum information measures of many-body systems often imply a measure with multi- or two regions such as bipartite charge fluctuations within the ground state revealing the logarithmic profile of the entanglement entropy in a quantum wire. Here, we introduce a new method from the bipartite current fluctuations and the divergence theorem. They reveal the fractional charges related to ground-state energetics and the proximity to Mott physics in the same ballistic quantum wires. This also encodes the behavior of the electron Green's function in space. With metallic gates on both sides of an interface to implement the protocol introducing the two macroscopic domains, bipartite current fluctuations can reveal an additional localized bound state associated to the topological Jackiw-Rebbi model, coexisting with the fractional charges. Through the Density Matrix Renormalization Group (DMRG) algorithm we introduce a quantum spin chain analogue.

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