IMA™ - Hyperspectral Fluorescence Microscope - VISNIR

Specifications

Spectral Range: 400 – 1700 nm
Spectral Resolution: 2.5 nm
Detection Spectral Range: 400 – 1650 nm
Excitation Laser Wavelength: 532nm, Other
Magnification: 20
Sample Stage (manual Or Motorized): X, Y, Z
Microscope: Upright or inverted
Spatial Resolution: sub-micron
Maximum Scanning Speed: 150 ms
Wavelength Absolute Accuracy: 0.25 nm
Epifluorescence Filter: Triple Filter Fluo available
Camera: InGaAs, CCD, EMCCD
Other Filters: Filter wheel (up to six filters)
Modules: Electroluminescence, Darkfield (Oil or Dry)
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Features

IMA™ - Hyperspectral Fluorescence Microscope comes with the following important features:



  • Fast global mapping (non-scanning)

  • High spatial and spectral resolution

  • Access to the second biological window

  • Attenuated tissue absorbance

  • High depth of penetration

  • Low scattering

  • Limited autofluorescence

  • Non-destructive analysis

  • Available measurements: PL, EL, reflectance, transmittance

  • Customization available

  • Complete system (source, microscope, camera, filter, software)

Applications

IMA™ - Hyperspectral Fluorescence Microscope is ideal for the following applications



  • Characterization of solar cells

  • Quality control of semiconductor devices

  • Map of: composition, defects, stress, constraint, etc.

  • Monitor spectral information

  • Changes in intensity of single emitters

  • Shifts in wavelength

  • Spectral bandwidth variations


AS WELL AS IN VIVO APPLICATIONS:



  • Imaging of multiplexed emitters

  • Long-term sensing


An example:
Single wall nanotubes (SWNTs) emission bands are narrow (~ 20 nm) and each band corresponds to unique (n, m) species (chiralities). With IR hyperspectral microscopy, it is possible to separate these species, with single SWNT spatial resolution on surfaces, in live cells (in vivo), and in vitro.