AIRsight


 Applications














 Li-Ion Battery  Multilayer Film                                  Microscope Image of
                                                                  Multilayer Film Cross Section  Interior


 This is an example of analyzing the negative electrode material from a lithium-ion battery.  This is an example of analyzing a multilayer  lm.  Surface layer
 Raman area mapping can be used to visualize the detailed distribution of components and structural characteristics   The distribution of each component can be visualized by using infrared
 in substances (crystallinity, defects, etc.). Therefore, it is useful for evaluating products and materials in R&D   and Raman area mapping to analyze a cut cross section from the  lm.
 applications.
 Note: In the chemical image shown, the red areas indicate high concentrations of the component and blue areas indicate low concentrations.












              Infrared Area Mapping Results  Chemical Image Created from Peak   Raman Area Mapping Results  Chemical Image Created from Peak
             Chemical Image of Phthalate Esters  Areas between 1551 and 1624 cm -1  Chemical Image of Titanium   Area Values between 345 and 508 cm -1
 Microscope Image of Negative   Raman Area Mapping Results  Chemical Image Created from Peak Area Values   Oxide (Rutile)
 Electrode Material  Chemical Image of Graphite   between 1482 and 1703 cm -1
 (G-Band)



 Polymorphic Crystal  Automotive Paint Coating



 This is an example of analyzing monohydrate and anhydrous forms of caffeine.  This is an example of analyzing an automotive paint coating. Samples with characteristics that make it dif cult to
 Raman spectra can differentiate between compounds that have identical chemical structures but with different   cut a cross section can be evaluated by analyzing the component distribution in the depth direction by Raman
 crystal polymorphisms. Evaluating the crystal form of substances with different solubility or ef cacy characteristics   spectroscopy and evaluating the degradation status or other criteria from the surface.
 is useful for controlling crystal formation during pharmaceutical manufacturing processes.  A separate mapping program (P/N 206-35093-41) is required.


                                      X                       X
 – Caffeine monohydrate: C 8 H 10 N 4 O 2 ·H 2 O  Y        Z
 – Caffeine anhydrous: C 8 H 10 N 4 O 2



 1656 cm -1 -1
 1656 cm
 887 cm -1 -1
 887 cm

                    Shiny Exterior    Microscope Image of Automotive   Raman Depth (Line) Mapping   Chemical Image Created from
                                           Paint Coating             Results        Peak Area Values between 1383
                                     (Blue circles: Line axis in X-direction)  Chemical Image of Acrylic Resin  and 1510 cm -1
 Raman Spectra of Caffeine Monohydrate and Caffeine Anhydrous  Enlargement of Raman Spectra
  (Peak differences indicated with blue arrows)





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