# Charge-spin mutual entanglement: A case study by exact diagonalization   of the one hole doped $t$-$J$ loop

**Authors:** Wayne Zheng, Zheng-Yu Weng

arXiv: 1703.04255 · 2018-10-22

## TL;DR

This study uses exact diagonalization to explore how a single hole doped into a finite-size Heisenberg loop exhibits quantum critical points, charge incoherence, and charge-spin entanglement, revealing complex many-body quantum interference effects.

## Contribution

It introduces the concept of charge-spin mutual entanglement to characterize charge incoherence and quantum criticality in doped Mott insulators, highlighting the role of sign structure.

## Key findings

- Multiple quantum critical points with momentum jumps are identified.
- Charge incoherence and translational symmetry breaking are observed.
- Removing the sign structure eliminates quantum criticality and charge incoherence.

## Abstract

A doped Mott insulator exhibits peculiar properties associated with its singular sign structure. As a case study, we investigate the ground state and excitations of finite-size Heisenberg loops doped with one hole by exact diagonalization. We find that there appear a series of quantum critical points (QCPs), which separate regimes by distinct total momenta along the axis of the ratio $J/t$ ($J$ and $t$ denote the superexchange coupling and hopping integral, respectively). Each QCP involves a crystal momentum jump with level crossing or merging of lowest energy levels. In contrast to the conserved total momentum, however, a broad momentum distribution of \emph{individual} electrons is also found, indicating charge incoherence/translational symmetry breaking in violation of the one-to-one correspondence. Such a charge incoherence is further related to quantum fluctuations or the transverse part of ${\bf S}^2=3/4$ with $S^z=\pm 1/2$ in the one-hole ground state. Turning off the phase-string sign structure, by contrast, we show that the total momentum of the ground state reduces to null in the whole regime of $J/t$ with no more QCP or incoherence. We introduce the so-called charge-spin mutual entanglement to characterize these novel properties, with the entanglement spectrum providing additional information on the charge incoherence, which capture the nature of strong correlation due to the many-body quantum interference.

## Full text

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## Figures

10 figures with captions in the complete paper: https://tomesphere.com/paper/1703.04255/full.md

## References

20 references — full list in the complete paper: https://tomesphere.com/paper/1703.04255/full.md

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Source: https://tomesphere.com/paper/1703.04255