We demonstrate that mid-infrared surface phonon polariton propagation on a SiC crystal can be imaged by scattering-type near-field optical microscopy. From the infrared images, we measure the wave vector and the propagation length of locally excited surface phonon polaritons. Our method can be also applied to surface plasmon polaritons and allows to study surface polaritons in subwavelength-scale structures.

Topics
Ferroelectric materials, Phonons, Surface plasmon polaritons, Demodulators, Data storage and retrieval, Scanning probe microscopy, Interferometry, Optical interference, Optical properties, Surface optics
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Note here that 4H–SiC has a hexagonal crystal structure and the anisotropic dielectric properties have to be taken into account., in contrast to the surface plasmon polariton dispersion on metals, kp,x=ωcεmetalεmetal+1.

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© 2005 American Institute of Physics.
2005
American Institute of Physics
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