Variational wavefunction for Mott insulator at finite $U$ using ancilla qubits
Abstract
The Mott regime with finite offers a promising platform for exploring novel phases of matter, such as quantum spin liquids (QSL) that exhibit fractionalization and emergent gauge field. Here, we provide a new class wavefunction, dubbed ancilla wavefunction, to capture both charge and spin (gauge) fluctuations in QSLs at finite . The ancilla wavefunction can unify the Fermi liquid and Mott insulator phases with a single variation parameter tuning the charge gap. As , the wavefunction reduces to the Gutzwiller projected state, while at , it is effectively equivalent to applying an inverse Schrieffer-Wolff transformation to the Gutzwiller projected state. This wavefunction can be numerically simulated in the matrix product state representation, and its performance is supported by numerical results for both one- and two-dimensional Hubbard models. Besides, we propose the possibility of a narrow regime of fractional Fermi liquid phase between the usual Fermi liquid and the Mott insulator phases close to the metal insulator transition -- a scenario typically overlooked by the conventional slave rotor theory. Our ancilla wavefunction offers a novel conceptual framework and a powerful numerical tool for understanding Mott physics.
Cite
@article{arxiv.2409.07512,
title = {Variational wavefunction for Mott insulator at finite $U$ using ancilla qubits},
author = {Boran Zhou and Hui-Ke Jin and Ya-Hui Zhang},
journal= {arXiv preprint arXiv:2409.07512},
year = {2024}
}
Comments
This is a rewriting of a previous preprint arXiv:2307.16038 . We have added a new coauthor and new results