%0 Journal Article %1 ochs2021nanoscale %A Ochs, Maximilian %A Zurak, Luka %A Krauss, Enno %A Meier, Jessica %A Emmerling, Monika %A Kullock, René %A Hecht, Bert %D 2021 %J Nano Letters %K experiment modes nano-optics plasmon waveguides %R 10.1021/acs.nanolett.1c00182 %T Nanoscale Electrical Excitation of Distinct Modes in Plasmonic Waveguides %U https://pubs.acs.org/doi/10.1021/acs.nanolett.1c00182 %X The electrical excitation of guided plasmonic modes at the nanoscale enables integration of optical nanocircuitry into nanoelectronics. In this context, exciting plasmons with a distinct modal field profile constitutes a key advantage over conventional single-mode integrated photonics. Here, we demonstrate the selective electrical excitation of the lowest-order symmetric and antisymmetric plasmonic modes in a two-wire transmission line. We achieve mode selectivity by precisely positioning nanoscale excitation sources, i.e., junctions for inelastic electron tunneling, within the respective modal field distribution. By using advanced fabrication that combines focused He-ion beam milling and dielectrophoresis, we control the location of tunnel junctions with sub-10 nm accuracy. At the far end of the two-wire transmission line, the guided plasmonic modes are converted into far-field radiation at separate spatial positions showing two distinct orthogonal polarizations. Hence, the resulting device represents the smallest electrically driven light source with directly switchable polarization states with possible applications in display technology.

@article{ochs2021nanoscale, abstract = {The electrical excitation of guided plasmonic modes at the nanoscale enables integration of optical nanocircuitry into nanoelectronics. In this context, exciting plasmons with a distinct modal field profile constitutes a key advantage over conventional single-mode integrated photonics. Here, we demonstrate the selective electrical excitation of the lowest-order symmetric and antisymmetric plasmonic modes in a two-wire transmission line. We achieve mode selectivity by precisely positioning nanoscale excitation sources, i.e., junctions for inelastic electron tunneling, within the respective modal field distribution. By using advanced fabrication that combines focused He-ion beam milling and dielectrophoresis, we control the location of tunnel junctions with sub-10 nm accuracy. At the far end of the two-wire transmission line, the guided plasmonic modes are converted into far-field radiation at separate spatial positions showing two distinct orthogonal polarizations. Hence, the resulting device represents the smallest electrically driven light source with directly switchable polarization states with possible applications in display technology.}, added-at = {2021-04-30T18:00:58.000+0200}, author = {Ochs, Maximilian and Zurak, Luka and Krauss, Enno and Meier, Jessica and Emmerling, Monika and Kullock, René and Hecht, Bert}, biburl = {https://www.bibsonomy.org/bibtex/2f9082f086f18593c8c42f9cd06036883/ep5optics}, doi = {10.1021/acs.nanolett.1c00182}, interhash = {39b2cbe77cf0e698464421cc2c304a03}, intrahash = {f9082f086f18593c8c42f9cd06036883}, journal = {Nano Letters}, keywords = {experiment modes nano-optics plasmon waveguides}, month = {04}, timestamp = {2021-08-02T13:12:44.000+0200}, title = {Nanoscale Electrical Excitation of Distinct Modes in Plasmonic Waveguides}, url = {https://pubs.acs.org/doi/10.1021/acs.nanolett.1c00182}, year = 2021 }