IMA PL VIS | NEW: IMA PL IR | |
SPECTRAL RANGE | 400 - 1000 nm | 900 - 1700 nm |
EXCITATION WAVELENGTHS | 447 nm, 532 nm, 635 nm, 660 nm | 785 nm, 808 nm, 980 nm |
SPECTRAL RESOLUTION | < 2.5 nm | < 4 nm |
SPATIAL RESOLUTION | Sub-micron | |
MICROSCOPE | Upright | |
OBJECTIVES | 20X, 50X, 100X | |
MAXIMUM SAMPLE FORMAT | 4" x 4" (10 cm x 10 cm) | |
X, Y TRAVEL RANGE | 76 mm x 52 mm | |
Z STAGE RESOLUTION | 1 µm | |
MAXIMUM SCANNING SPEED | 150 ms | |
WAVELENGTH ABSOLUTE ACCURACY | 0.25 nm | 0.5 nm |
VIDEO MODE | Caméra megapixel pour visualiser l'échantillon | |
PREPROCESSING | Filtrage spatial, outils statistiques, extraction de spectres, normalisation des données, calibration spectrale | |
HYPERSPECTRAL DATA FORMAT | FITS, HDF5 | |
SINGLE IMAGE DATA FORMAT | JPG, PNG, TIFF, CSV, PDF, SGV | |
SOFTWARE | PHySpec™ control and analysis | |
DIMENSIONS | ≈ 40" x 30" x 30" (102 cm x 76 cm x 76 cm) | |
WEIGHT | ≈ 80 Kg | |
*UPDATES | IMA PL VIS | IMA PL IR |
LASER | Additional excitation wavelengths available | |
HI CAMERA | Back-illuminated camera | N/A |
EMCCD | N/A | |
HIGH-RESOLUTION MODULE | N/A |
900-1700 nm, FWHM < 1 nm |
2017. A Carbon Nanotube Optical Reporter Maps Endolysosomal Lipid Flux
2017. A Carbon Nanotube Optical Sensor Reports Nuclear Entry via a Noncanonical Pathway
2017. A carbon nanotube reporter of microRNA hybridization events in vivo
2016. Optical Imaging of Light-Induced Thermopower in Semiconductors
2014. Quantitative luminescence mapping of Cu(In,Ga)Se2 thin-film solar cells
2012. Contactless mapping of saturation currents of solar cells by photoluminescence
2012. Conic hyperspectral dispersion mapping applied to semiconductor plasmonics
2012. Luminescence Imaging of Extended Defects in SiC via Hyperspectral Imaging
2011. Characterisation of Solar Cells Using Hyperspectral Imager
2011. A photoluminescence-based quantum semiconductor biosensor for rapid in situ detection of Escherichia coli
2010. Photoluminescence and Electroluminescence mapping of CIGS Solar Cell
Presentation of Photon etc's Hyperspectral Microscope
From solar cells to live cell imaging, our fast and all-in-one hyperspectral microscope IMA™ offers unmatched image and data quality.
Photon etc's Global Imaging Technology
This video shows the conceptual difference between hyperspectral global imaging and raster scan (line-scan, push- broom). With global imaging, the gain in acquiring 3D data, 2D spatial and 1D spectral, is important since only a few monochromatic images are required to cover the complete spectral range where one needs to take the full spectrum for each point or line in the image with other technologies.