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Beilstein J. Nanotechnol. 2012, 3, 312–323, doi:10.3762/bjnano.3.35
Figure 1: Nano-FTIR basic interaction. Focused infrared light incident from the upper left excites a nanofocu...
Figure 2: Polished section of Mytilus edulis viewed in monochromatic s-SNOM (980 cm−1). (a) Topography of the...
Figure 3: Nano-FTIR spectral line scan across the interface between calcite and aragonite layers; (a) Topogra...
Figure 4: Nano-FTIR spectra of M. edulis obtained from Figure 3b and Figure 3c by averaging over the ranges indicated in Figure 3b by th...
Figure 5: Nano-FTIR spectral line scans as in Figure 3; (a–c) Topography, amplitude and phase spectra ca. 300 nm belo...
Figure 6: Polished section of Mytilus edulis viewed in monochromatic s-SNOM (980 cm−1), continued from Figure 2; (a) ...
Figure 7: Tubule in human dentin and its surrounding imaged by (a,b) nano-FTIR where the topography (a) is ac...
Figure 8: Local infrared spectra registered by nano-FTIR at positions 1–4 in Figure 7b (colors), and further away on e...
Figure 9: Dentin characteristics along line scans marked x (left part) and y (right part) in Figure 7; SEM intensity ...
Figure 10: Tubule in human dentin near the enamel, imaged by nano-FTIR in which the infrared amplitude image (...
Figure 11: "Phosphate" in M. edulis. High-resolution images (similar to Figure 1) of the dotted-box areas, 1.0 × 1.2 µm...
Figure 12: Normalized infrared resonance of phosphate; (a) of dentin and enamel measured by nano-FTIR (colors ...