Design of single-mode waveguides for enhanced light-sound interaction in honeycomb-lattice silicon slabs

We present the design of two waveguides (ladder and slot-ladder waveguides) implemented in a silicon honeycomb photonic-phononic crystal slab, which can support slow electromagnetic and elastic guided modes simultaneously. Interestingly, the photonic bandgap extends along the first Brillouin zone; s...

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Detalles Bibliográficos
Autores: Escalante Fernández, José María, Laude, Vincent, Martínez, Alejandro|||0000-0001-5448-0140
Tipo de recurso: artículo
Fecha de publicación:2014
País:España
Institución:Universitat Politècnica de València (UPV)
Repositorio:RiuNet. Repositorio Institucional de la Universitat Politécnica de Valéncia
Idioma:inglés
OAI Identifier:oai:riunet.upv.es:10251/44795
Acceso en línea:https://riunet.upv.es/handle/10251/44795
Access Level:acceso abierto
Palabra clave:Waveguides
Optomechanics
Photon-phonon interaction
Photonic crystals
Photonic band gap
Crystal slabs
Phonons
Periodic structures
Phononic Crystals
Phoxonic crystal waveguides
Optomechanical coupling
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Descripción
Sumario:We present the design of two waveguides (ladder and slot-ladder waveguides) implemented in a silicon honeycomb photonic-phononic crystal slab, which can support slow electromagnetic and elastic guided modes simultaneously. Interestingly, the photonic bandgap extends along the first Brillouin zone; so with an appropriate design, we can suppress propagation losses that arise coupling to radiative modes. From the phononic point of view, we explain the slow elastic wave effect by considering the waveguide as a chain of coupled acoustic resonators (coupled resonant acoustic waveguide), which provides the mechanism for slow elastic wave propagation. The ladder waveguide moreover supports guided phononic modes outside the phononic bandgap, similar to photonic slab modes, resulting in highly confined phononic modes propagating with low losses. Such waveguides could find important applications to the observation of optomechanical and electrostriction effects, as well as to enhanced stimulated Brillouin scattering and other opto-acoustical effects in nanoscale silicon structures. We also suggest that they can be the basis for a "perfect" photonic-phononic cavity in which damping by coupling to the surroundings is completely forbidden.