Raman microscope with ultra-high speed imaging capability
Features
Only a few minutes of acquisition time is required for Raman imaging.
Clear observation of fine structure by high spatial resolution of 0.3micro at x, y direction and 0.7micro at z direction.
Easy to learn and use software for all users.
High peak position accuracy (0.1 cm-1) enabling to measure the strain of the crystals.
One simple mouse click enabling to measure any location on the sample observed with CCD camera.
Small footprint by compact design.
Outline of RAMAN-11
RAMAN-11 is a next generation laser microscope observing an image of a sample with Raman scattering lights emitted from the molecules. Raman spectroscopy technique used for RAMAN-11 gives researchers the knowledge for the details of constituent elements of organelles or protein. By observing the Raman scattering lights emitted from the molecules of the living cells, distribution of the molecules can be imaged with the colors (wavelength) unique to those molecules without using the staining method.
When a molecule is illuminated with a monochromatic laser beam, a portion of the incident light is scattered with different color. This scattered light is called "Raman scattering" for the name of the discoverer. The Raman scattered light tells us about the molecular is specific to the molecule, like a fingerprint. In addition, the Raman scattered light from a crystal gives the lattice condition of the crystal such as distortion, defects and impurity, and therefore can be utilized for crystal analysis.
Due to the weakness of Raman scattered light, conventional micro Raman system took a long time for one point measurement and scanned the sample point by point to take images. The scanning speed of this method is very slow. RAMAN-11 has noteworthy capable to accelerate the imaging speed. Nanophoton's original technology of a flying spot scanning technique contributes 100 times faster image acquisition than conventional systems.
Examples of observation
A Raman image of fullerene(C60) schowing the intensity peak at 1470cm-1. The fullerene distribution generated on the substrate is observed.
Raman image of non-stained living cardiomyocytes. Raman peaks of lipid, protein, and nucleic acid are assigned to red, green and blue. Subcellular organelles and bio-molecules are observed.
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Raman observation image of a paint surface. With an unknown mixture of substances, the surface state and the anamorphism can be observed and analyzed at the microscopic scale. |
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Phase contrast image(left) and Raman Image(center) of a white blood cell capturing foreign body. |
NanoPhoton 三維掃描共聚焦拉曼系統(tǒng)
Nonophoton's Laser Raman Microscope took a large step as RAMANplus. The RAMANplus has a built-in video rate confocal reflection system that acquires the three-dimensional surface profile very fast in advance of Raman measurenment. After the Raman measurement, the RAMANplus automatically appends the Raman chemical information to the three-dimensional profile.
Features
Quick measurement of three-dimensional surface profile
Quick search of interesting points in bumpy samples
Ultra-fast and high-definition Raman imaging
Easy link of chemical information to 3D-surface profile
Technologies
Observation example of Diamond file
The reflected light confocal observation gives the precise extended focus reflected image (grey color). The Raman observation gives the data of the crystal quality. These data are acquired and overlaid automatically.
Green: High quality diamond
Yellow: Low quality diamond
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