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Experimental realization of an extended Fermi-Hubbard model using a 2D lattice of dopant-based quantum dots

Xiqiao Wang, Ehsan Khatami, Fan Fei, Jonathan Wyrick, Pradeep Namboodiri, Ranjit V. Kashid, Albert F. Rigosi, Garnett W. Bryant, Richard M. Silver

2022Nature Communications74 citationsDOIOpen Access PDF

Abstract

The Hubbard model is an essential tool for understanding many-body physics in condensed matter systems. Artificial lattices of dopants in silicon are a promising method for the analog quantum simulation of extended Fermi-Hubbard Hamiltonians in the strong interaction regime. However, complex atom-based device fabrication requirements have meant emulating a tunable two-dimensional Fermi-Hubbard Hamiltonian in silicon has not been achieved. Here, we fabricate 3 × 3 arrays of single/few-dopant quantum dots with finite disorder and demonstrate tuning of the electron ensemble using gates and probe the many-body states using quantum transport measurements. By controlling the lattice constants, we tune the hopping amplitude and long-range interactions and observe the finite-size analogue of a transition from metallic to Mott insulating behavior. We simulate thermally activated hopping and Hubbard band formation using increased temperatures. As atomically precise fabrication continues to improve, these results enable a new class of engineered artificial lattices to simulate interactive fermionic models.

Topics & Concepts

Hubbard modelCondensed matter physicsDopantHamiltonian (control theory)PhysicsQuantumQuantum dotFermi Gamma-ray Space TelescopeLattice (music)Materials scienceQuantum mechanicsDopingSuperconductivityMathematical optimizationMathematicsAcousticsQuantum and electron transport phenomenaPhysics of Superconductivity and MagnetismElectronic and Structural Properties of Oxides
Experimental realization of an extended Fermi-Hubbard model using a 2D lattice of dopant-based quantum dots | Litcius