Dynamic mass generation on two-dimensional electronic hyperbolic lattices (2302.04864v2)

Abstract: Free electrons hopping on hyperbolic lattices embedded on a negatively curved space can foster (a) Dirac liquids, (b) Fermi liquids, and (c) flat bands, respectively characterized by a vanishing, constant, and divergent density of states near the half filling. From numerical self-consistent mean-field Hartree analyses, we show that nearest-neighbor Coulomb and on-site Hubbard repulsions respectively give rise to charge-density-wave and antiferromagnetic orders featuring staggered patterns of average electronic density and magnetization in all these systems, when the hyperbolic tessellation is accomplished by periodic arrangements of even $p$-gons. Both quantum orders dynamically open mass gaps near the charge neutrality point via spontaneous symmetry breaking. Only on hyperbolic Dirac materials these orderings take place via quantum phase transitions (QPTs) beyond critical interactions, which however decrease with increasing curvature, showcasing curvature-induced weak-coupling QPTs. We present scaling of these masses with the corresponding interaction strengths.

Dynamic Mass Generation on Two-Dimensional Electronic Hyperbolic Lattices

The research discussed in this paper investigates the electronic properties of two-dimensional quantum materials when electrons hop on hyperbolic lattices, which are constructed on surfaces of negative curvature. The paper leverages numerical self-consistent Hartree-Fock analyses to examine the resultant quantum orders facilitated by nearest-neighbor (NN) and on-site Coulomb interactions. The emergence of these orders and their dependence on spatial curvature presents significant insights into both the interaction-driven phenomena and curvature-induced quantum phase transitions in such systems.

Major Findings

The paper categorizes electronic hyperbolic lattices based on their density of states (DOS) at half-filling into Dirac liquids, Fermi liquids, and flat bands. These categories respectively exhibit vanishing, constant, and divergent DOS at the charge neutrality point. The lattice geometry is defined by a pair of integers, $p$ and $q$, denoting the periodic arrangements of regular polygons (p-gons) and the number of nearest neighbors connected to each vertex.

• Charge-Density-Wave (CDW) Formation: The paper shows that NN Coulomb interactions $V$ induce CDW orders, manifesting staggered patterns of electronic density. Systems with Fermi liquids and flat bands readily exhibit CDW ordering even at infinitesimal interaction strength due to their finite or divergent DOS. However, Dirac liquids require a finite interaction strength to undergo a quantum phase transition (QPT) into a CDW ordered state, attributed to their linearly vanishing DOS.
• Antiferromagnetic (AFM) Ordering: Similarly, on-site Hubbard repulsions $U$ yield AFM orders with staggered magnetization patterns. The AFM order also arises at finite interaction strength in Dirac liquids, with critical couplings decreasing systematically with increasing curvature, supporting the hypothesis of curvature-induced weak coupling QPTs.

Numerical Results and Implications

Numerical analyses confirm that CDW and AFM orders dynamically open mass gaps at the charge neutrality point, insulating the system. The critical interaction strengths for both orders decrease with increasing $p$ and curvature in Dirac materials. A notable result is the ratio $U_c/V_c \approx 2.4$ for these lattices, which deviates from the expected mean-field value of $3$, potentially due to boundary effects in lattices with open boundary conditions.

These findings have significant implications for understanding strong-correlated electron phenomena and demonstrate that curvature influences interaction strengths required for quantum ordering. Moreover, this could provide insights into novel quantum phases in hyperbolic lattice systems, potentially paving the way for experimental verification in controlled systems like designer materials or cold atomic setups.

Future Directions

The research opens avenues to explore other exotic correlated phases such as topological Mott insulators and superconductors. Further studies might involve quantum Monte Carlo simulations to incorporate quantum fluctuations, especially for non-Euclidean lattices without facing the sign problem.

Potential experimental observation of these results can be undertaken using designer quantum systems with tunable parameters, where hyperbolic lattices are engineered for controlled investigation of quantum phase dynamics. This could also extend to cold atomic systems where analogous setups could help explore interaction-dependent phenomena in hyperbolically curved spaces.

This paper thus contributes to the broader understanding of how geometric and topological properties influence electronic interactions, offering a rich venue for both theoretical and experimental advancements in the paper of quantum materials.