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Transmission SNOM microscopy

Like conventional optical microscopy, the SNOM can be performed in transmission or in reflection. The most common method is the transmission SNOM in which a thin, transparent sample is excited by the tip (i.e., illumina-... [Pg.223]

SD spinodal decomposition SEM scanning electron microscopy SNOM scanning near-field optical microscopy STED stimulated emission depletion SWNT single wall carbon nanotube TEM transmission electron microscopy... [Pg.132]

Scanning near-field optical microscopy (SNOM) or near-field scanning optical microscopy (NSOM) Shear force microscopy (ShFM) Aperture SNOM (ASNOM) - Transmission ASNOM (T-ASNOM)... [Pg.595]

Scanning Near-Field Optical Microscopy (SNOM) Aperture SNOM (ASNOM) Collection ASNOM (C-ASNOM) Emission ASNOM (E-ASNOM) Evanescent Field SNOM (EF-SNOM) Nonaperture ASNOM (NA-SNOM) Shear Force Microscopy Transmission Mode (TSNOM) Reflection Mode Luminescence Mode... [Pg.359]

The first application of the SNOM for the MO studies happened in 1992 [62], when it was demonstrated that near-field MO observation can be obtained in the same manner as conventional far-field observation— that is, by using two cross-polarizers. Betzig et al. [62] visualized 100-nm magnetic domains and claimed spatial resolution of 30-50 nm. The possibility of MO domain imaging was confirmed in both the transmission regime (Faraday geometry) [63,64] and the reflection regime (Kerr microscopy) [65-67]. [Pg.225]

The SNOM combines the possibilities of AFM and optical microscopy. On the one hand, it allows for probing of the surface and obtaining information on the topography. On the other hand, in aperture SNOM, the probe contains an aperture, and the sample can be illuminated locally (Fig. 5). The diameter of the aperture at the end of the probe is typically of the order of 50-100 nanometer, and therefore, the illuminating spot is not diffraction limited. Both transmission and tluorescence in combination with polarization provide appropriate contrast mechanisms. [Pg.1398]

Fig. 9.3 Imaging via near-field microscopy (a) SNOM in transmission (b) SNOM in reflection (c) PSTM. Fig. 9.3 Imaging via near-field microscopy (a) SNOM in transmission (b) SNOM in reflection (c) PSTM.
See other pages where Transmission SNOM microscopy is mentioned: [Pg.9]    [Pg.261]    [Pg.38]    [Pg.36]    [Pg.226]    [Pg.170]    [Pg.170]    [Pg.1414]    [Pg.677]    [Pg.830]    [Pg.513]    [Pg.164]   


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