EMILIE
Nanomechanical infrared analyzer
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I use much less sample for one measurement and lower LoDs can be reached
Research
I have worked with EMILIE (together with the chips and PHILL) for several months for FTIR and QCL spectroscopy. The exchange of chips is quickly done and handling of the PHILL software is very easy to learn. I find it especially intriguing to measure low concentrations of dry analytes that are adsorbed on a surface; compared to other common reflectance spectroscopy methods, I use much less sample for one measurement and lower LoDs can be reached.
Review Date: 8 Aug 2024 | Invisible-Light Labs GmbH
With its unique nanoelectromechanical sensing technology, EMILIE allows you to explore new frontiers in the characterization of aerosols, nanoparticles, biopharmaceuticals, thin films, and more.
Features
- High sensitivity without cryogenic cooling
- Picogram detection limit
- Large spectral range (NIR to FIR)
- Fast and easy sampling of aerosols and nanoparticle dispersions
- Compatible with commercially available FTIR spectrometers
Applications
- Bulk chemical characterization of nanomaterials
- Chemical analysis of non-volatile and semi-volatile analytes
- Thin film analysis
- Chemical composition of aerosols
- Nanoplastics identification
Unique technology
EMILIE™ uses unique nanoelectromechanical sensing (NEMS) technology.
Nanomechanical photothermal spectroscopy: An introduction to the EMILIE technology
Photothermal spectroscopy is an analytical technique used to probe the absorption properties of materials through the ensuing non-radiative relaxation processes that generate heat. Invisible-Light Labs introduces EMILIE™, a photothermal infrared spectroscopy technique based on a nanoelectromechanical system (NEMS). Discover how EMILIE™ is a unique and powerful analytical tool due to its exceptionally wide spectral range, insensitivity to scattering and reflections, efficiency and versatility in sampling a wide variety of materials, possibility for in-situ thermal desorption analysis, and exceptional sensitivity at room temperature with a limit of detection (LoD) in the picogram range.
The next frontier in nanoelectromechanical photothermal infrared spectroscopy
Discover how Invisible-Light Labs is redefining nanoscale analysis with EMILIE, boosting sensitivity and cutting sampling times for breakthroughs in environmental monitoring, nanotechnology, and beyond
