Mechanical Kerr Nonlinearity of Wave Propagation in an On-Chip Nanoelectromechanical Waveguide
M. Kurosu, D. Hatanaka, H. Yamaguchi
Abstract
We experimentally and numerically demonstrate nonlinear flexural wave propagation using an on-chip nanoelectromechanical waveguide. More specifically, third-order nonlinear phenomena of self-phase modulation, cross-phase modulation, and four-wave mixing caused by the mechanical Kerr effect are realized. Our experimental observations are correctly described by the nonlinear Schr\"odinger equation. The nanomechanical and integratable platform enables on-chip manipulation of mechanical wave propagation, thus offering the potential to develop novel functional devices and study nonlinear mechanical phenomena.
Topics & Concepts
Nanoelectromechanical systemsNonlinear systemKerr effectFlexural strengthKerr nonlinearityNonlinear opticsMixing (physics)Wave propagationWaveguidePhysicsOpticsMaterials scienceMechanical systemFour-wave mixingDynamics (music)AcousticsOptoelectronicsCross-polarized wave generationNonlinear opticalMechanical and Optical ResonatorsNonlinear Photonic SystemsAdvanced Fiber Laser Technologies