Litcius/Paper detail

Topological Band Engineering of Lieb Lattice in Phthalocyanine-Based Metal–Organic Frameworks

Wei Jiang, Shunhong Zhang, Zhengfei Wang, Feng Liu, Tony Low

2020Nano Letters93 citationsDOI

Abstract

Topological properties of the Lieb lattice, i.e., the edge-centered square lattice, have been extensively studied and are, however, mostly based on theoretical models without identifying real material systems. Here, based on tight-binding and first-principles calculations, we demonstrate the Lieb-lattice features of the experimentally synthesized phthalocyanine-based metal–organic framework (MPc-MOF), which holds various intriguing topological phase transitions through band engineering. First, we show that the MPc-MOFs indeed have a peculiar Lieb band structure with 1/3 filling, which has been overlooked because of its unconventional band structure deviating from the ideal Lieb band. The intrinsic MPc-MOF presents a trivial insulating state, with its gap size determined by the on-site energy difference (ΔE) between the corner and edge-center sites. Through either chemical substitution or physical strain engineering, one can tune ΔE to close the gap and achieve a topological phase transition. Specifically, upon closing the gap, topological semimetallic/insulating states emerge from nonmagnetic MPc-MOFs, while magnetic semimetal/Chern insulator states arise from magnetic MPc-MOFs, respectively. Our discovery greatly enriches our understanding of the Lieb lattice and provides a guideline for experimental observation of the Lieb-lattice-based topological states.

Topics & Concepts

Lattice (music)Condensed matter physicsBand gapTopological insulatorSemimetalTopology (electrical circuits)Square latticeElectronic band structureTopological orderMaterials sciencePhysicsQuantum mechanicsQuantumIsing modelMathematicsAcousticsCombinatoricsTopological Materials and PhenomenaAdvanced Condensed Matter PhysicsGraphene research and applications
Topological Band Engineering of Lieb Lattice in Phthalocyanine-Based Metal–Organic Frameworks | Litcius