News Release

Observation of antichiral edge states in a circuit lattice

Peer-Reviewed Publication

Science China Press

Figure 1

image: (a) Photo of electric circuit in experiments. (b) The measured antichiral edge states. (c), (d) A Möbius strip configuration consisting of electric circuit and the propagation of antichiral edge states in experiments, respectively. view more 

Credit: @Science China Press

Originally formulated in the context of condensed matter physics, the Haldane model is an influential model of a two-dimensional topological insulator. It has also been realized in classical-wave metamaterial analogues of topological insulator, such as photonic crystals, acoustic crystals, and electric LC circuits.

Recently, theorists have shown that a modification to the Haldane model exhibits the novel phenomenon of antichiral edge sates, according to E. Colomés and M. Franz, scholars at Department of Physics and Astronomy and Quantum Matter Institute, University of British Columbia. Unlike the chiral edge states associated with the standard Haldane model, antichiral edge states possess the same propagation direction on opposite edges of a sample; the current carried by the edge states is compensated by counter-propagating bulk states. However, the modified Haldane model has thus far never been realized in any experimental setting. In condensed matter, it is extremely challenging to achieve since it requires an unusual configuration of magnetic vector potentials within each crystalline unit cell.

An article coauthored by Profs. ZhiHong Hang and Yidong Chong, from Soochow University and Nanyang Technological University respectively, provided the first experimental realization of a modified Haldane model, consisting of electrical circuit lattices. This study entitled "Observation of antichiral edge states in a circuit lattice", was published in SCIENCE CHINA Physics, Mechanics & Astronomy. These researchers provide direct experimental evidence that the circuit lattice exhibits edge states, and that their propagation is antichiral. Their experimental results are in good agreement not only with theory, but also with numerical circuit simulations. "It opens the door to further experimental explorations of the properties of antichiral edge states in a real physical system", these researchers stated.

"This work demonstrates the flexibility of electrical circuit lattices as an experimental platform for realizing lattice models with effective magnetic vector potentials", they explained. Previous researchers had shown how to use circuits to implement a very well-studied topological phase (the Chern insulator, i.e. the simplest two-dimensional topological insulator), whereas in their study they implemented a very novel and nontrivial model (the modified Haldane model).

This experiments also point to the intriguing possibility of using circuit lattices to explore models with Möbius strip geometries and other exotic configurations, which may be a rich avenue of future research.


See the article:

Y. Yang, D. Zhu, Z. H. Hang, and Y. D. Chong, Observation of antichiral edge states in a circuit lattice, Sci. China-Phys. Mech. Astron. 64(5), 257011 (2021).

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