Abstract
We highlight a general theory to engineer arbitrary Hermitian tight-binding lattice models in electrical LC circuits, where the lattice sites are replaced by the electrical nodes, connected to its neighbors and to the ground by capacitors and inductors. In particular, by supplementing each node with $n$ subnodes, where the phases of the current and voltage are the $n$ distinct roots of \emph{unity}, one can in principle realize arbitrary hopping amplitude between the sites or nodes via the \emph{shift capacitor coupling} between them. This general principle is then implemented to construct a plethora of topological models in electrical circuits, \emph{topolectric circuits}, where the robust zero-energy topological boundary modes manifest through a large boundary impedance, when the circuit is tuned to the resonance frequency. The simplicity of our circuit constructions is based on the fact that the existence of the boundary modes relies only on the Clifford algebra of the corresponding Hermitian matrices entering the Hamiltonian and not on their particular representation. This in turn enables us to implement a wide class of topological models through rather simple topolectric circuits with nodes consisting of only two subnodes. We anchor these outcomes from the numerical computation of the on-resonance impedance in circuit realizations of first-order ($m=1$), such as Chern and quantum spin Hall insulators, and second- ($m=2$) and third- ($m=3$) order topological insulators in different dimensions, featuring sharp localization on boundaries of codimensionality $d_c=m$. Finally, we subscribe to the \emph{stacked topolectric circuit} construction to engineer three-dimensional Weyl, nodal-loop, quadrupolar Dirac and Weyl semimetals, respectively displaying surface and hinge localized impedance.
Highlights
Simple topological models, such as the Su-SchriefferHeeger (SSH) [1,2,3] and the Bernevig-Hughes-Zhang (BHZ) model [4,5], have played a pivotal role in the development of topological condensed matter physics
By supplementing each node with n subnodes, where the phases of the current and voltage are the n distinct roots of unity, one can in principle realize arbitrary hopping amplitude between the sites or nodes via the shift capacitor coupling between them. This general principle is implemented to construct a plethora of topological models in electrical circuits, topolectric circuits, where the robust zero-energy topological boundary modes manifest through a large boundary impedance, when the circuit is tuned to the resonance frequency
We show how the hierarchy of the topological insulators can be realized in the topolectric platform in the case of a 2D second-order topological insulator by breaking the fourfold (C4) rotational symmetry of the parent firstorder phase (Fig. 12 below) and explore a related antiunitary symmetry-protected generalized second-order topological insulator on an electrical circuit (Fig. 13)
Summary
Simple topological models, such as the Su-SchriefferHeeger (SSH) [1,2,3] and the Bernevig-Hughes-Zhang (BHZ) model [4,5], have played a pivotal role in the development of topological condensed matter physics They provide an effective description of various topologically and symmetry-protected phases [6,7,8,9,10,11], which captures the topological invariant, boundary modes, and responses to external perturbations. Its form depends on the connectivity of the circuit elements through the nodes, which is used to engineer the parameters of a hopping model In this platform the impedance between the two nodes, related to the admittance matrix, can be used to locally detect the boundary modes [33] and serves as an electric circuit analog of a tunneling probe for topological crystals
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