%0 Journal Article %1 helbig2020generalized %A Helbig, Tobias %A Hofmann, Tobias %A Imhof, Stefan %A Abdelghany, Mohamed %A Kiessling, Tobias %A Molenkamp, Laurens W. %A Lee, Ching Hua %A Szameit, Alexander %A Greiter, Martin %A Thomale, Ronny %D 2020 %J Nat. Phys. %K c %N 7 %P 747--750 %R 10.1038/s41567-020-0922-9 %T Generalized bulk–boundary correspondence in non-Hermitian topolectrical circuits %U https://doi.org/10.1038/s41567-020-0922-9 %V 16 %X The study of the laws of nature has traditionally been pursued in the limit of isolated systems, where energy is conserved. This is not always a valid approximation, however, as the inclusion of features such as gain and loss, or periodic driving, qualitatively amends these laws. A contemporary frontier of metamaterial research is the challenge open systems pose to the characterization of topological matter. Here, one of the most relied upon principles is the bulk–boundary correspondence (BBC), which intimately relates the surface states to the topological classification of the bulk. The presence of gain and loss, in combination with the violation of reciprocity, has been predicted to affect this principle dramatically. Here, we report the experimental observation of BBC violation in a non-reciprocal topolectric circuit, which is also referred to as the non-Hermitian skin effect. The circuit admittance spectrum exhibits an unprecedented sensitivity to the presence of a boundary, displaying an extensive admittance mode localization despite a translationally invariant bulk. Intriguingly, we measure a non-local voltage response due to broken BBC. Depending on the a.c. current feed frequency, the voltage signal accumulates at the left or right boundary, and increases as a function of nodal distance to the current feed.

@article{helbig2020generalized, abstract = {The study of the laws of nature has traditionally been pursued in the limit of isolated systems, where energy is conserved. This is not always a valid approximation, however, as the inclusion of features such as gain and loss, or periodic driving, qualitatively amends these laws. A contemporary frontier of metamaterial research is the challenge open systems pose to the characterization of topological matter. Here, one of the most relied upon principles is the bulk–boundary correspondence (BBC), which intimately relates the surface states to the topological classification of the bulk. The presence of gain and loss, in combination with the violation of reciprocity, has been predicted to affect this principle dramatically. Here, we report the experimental observation of BBC violation in a non-reciprocal topolectric circuit, which is also referred to as the non-Hermitian skin effect. The circuit admittance spectrum exhibits an unprecedented sensitivity to the presence of a boundary, displaying an extensive admittance mode localization despite a translationally invariant bulk. Intriguingly, we measure a non-local voltage response due to broken BBC. Depending on the a.c. current feed frequency, the voltage signal accumulates at the left or right boundary, and increases as a function of nodal distance to the current feed.}, added-at = {2020-12-28T10:53:39.000+0100}, author = {Helbig, Tobias and Hofmann, Tobias and Imhof, Stefan and Abdelghany, Mohamed and Kiessling, Tobias and Molenkamp, Laurens W. and Lee, Ching Hua and Szameit, Alexander and Greiter, Martin and Thomale, Ronny}, biburl = {https://www.bibsonomy.org/bibtex/22dff0e2ac9977fb303a6e81aa99950c0/ctqmat}, day = 1, description = {Generalized bulk–boundary correspondence in non-Hermitian topolectrical circuits | Nature Physics}, doi = {10.1038/s41567-020-0922-9}, interhash = {5c39a5eccfad401471160512d588ab47}, intrahash = {2dff0e2ac9977fb303a6e81aa99950c0}, issn = {17452481}, journal = { Nat. Phys.}, keywords = {c}, month = {6}, number = 7, pages = {747--750}, refid = {Helbig2020}, timestamp = {2023-10-16T11:25:30.000+0200}, title = {Generalized bulk–boundary correspondence in non-Hermitian topolectrical circuits}, url = {https://doi.org/10.1038/s41567-020-0922-9}, volume = 16, year = 2020 }