%0 Journal Article %1 noauthororeditor %A Palatnik, Alexander %A Sudzius, Markas %A Meister, Stefan %A Leo, Karl %D 2021 %J Nanophotonics %K c %N 9 %P 2459-2465 %T One-dimensional planar topological laser %U https://www.degruyter.com/document/doi/10.1515/nanoph-2021-0114/html %V 10 %X Topological interface states are formed when two photonic crystals with overlapping band gaps are brought into contact. In this work, we show a planar binary structure with such an interface state in the visible spectral region. Furthermore, we incorporate a thin layer of an active organic material into the structure, providing gain under optical excitation. We observe a transition from fluorescence to lasing under sufficiently strong pump energy density. These results are the first realization of a planar topological laser, based on a topological interface state instead of a cavity like most of other laser devices. We show that the topological nature of the resonance leads to a so-called “topological protection”, i.e. stability against layer thickness variations as long as inversion symmetry is preserved: even for large changes in thickness of layers next to the interface, the resonant state remains relatively stable, enabling design flexibility superior to conventional planar microcavity devices.

@article{noauthororeditor, abstract = {Topological interface states are formed when two photonic crystals with overlapping band gaps are brought into contact. In this work, we show a planar binary structure with such an interface state in the visible spectral region. Furthermore, we incorporate a thin layer of an active organic material into the structure, providing gain under optical excitation. We observe a transition from fluorescence to lasing under sufficiently strong pump energy density. These results are the first realization of a planar topological laser, based on a topological interface state instead of a cavity like most of other laser devices. We show that the topological nature of the resonance leads to a so-called “topological protection”, i.e. stability against layer thickness variations as long as inversion symmetry is preserved: even for large changes in thickness of layers next to the interface, the resonant state remains relatively stable, enabling design flexibility superior to conventional planar microcavity devices.}, added-at = {2021-11-08T09:25:45.000+0100}, author = {Palatnik, Alexander and Sudzius, Markas and Meister, Stefan and Leo, Karl}, biburl = {https://www.bibsonomy.org/bibtex/2c266c7b9853993ef12d5a08250514e19/ctqmat}, day = 07, description = {One-dimensional planar topological laser}, interhash = {40c05431d35efef3ced4566d426e802e}, intrahash = {c266c7b9853993ef12d5a08250514e19}, journal = {Nanophotonics}, keywords = {c}, month = {07}, number = 9, pages = {2459-2465}, timestamp = {2023-11-24T11:44:03.000+0100}, title = {One-dimensional planar topological laser}, url = {https://www.degruyter.com/document/doi/10.1515/nanoph-2021-0114/html}, volume = 10, year = 2021 }