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Basics: Research that demands a Hyperspectral Microscope must be capable of working with very weak spectral signals. This means that an optimum instrument must deliver the highest possible light throughput to the detector, without throwing away light.
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Light throughput: The PARISS Hyperspectral microscope comes very close to ideal by transmitting up to 90% of all wavelength from 365 to 920 nm to the detector. Prism systems do not throw away light into higher orders, or suffer from efficiencly drops "off blaze."
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Sample types: The PARISS Hyperspectral Microscope system is designed to handle complex
heterogeneous samples such as nanoparticles, histological, cytological, industrial, physics and chemistry samples.
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Journal Covers: Researchers using PARISS have made the front cover of journals four times Click to visit.
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Key functions: Nanoparticles in dark-field scatter, spectral segmentation and spectral mapping in fluorescence, transmission, absorption, reflection and bright-field.
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Multiple fluorophores: Identify any or all of up to 15 spectrally overlapping fluorophores, simultaneously, anywhere in a sample field of view
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Resolution: 1 nm; Spectral range: 365 to 920 nm simultaneously
Quantum Efficiency Correction: Radiometric after correction with a NIST traceable lamp
