The Thermo Scientific DXR3 Flex Raman Spectrometer is a research-grade benchtop Raman spectrometer specifically designed for integration with other analytical techniques. This compact spectrometer uses the same design and optics as advanced spectrometers in the Thermo Scientific DXR3 Raman Spectrometer research product family. Thus, it provides transportability and hyphenation without compromising data quality. Whether you need to complement your materials understanding with chemical identification, correlate chemistry and materials performance, or monitor a process in real time, the DXR3 Flex Raman Spectrometer can help you quickly reach your goals.
Often referred to as “Raman engine,” the DXR3 Flex Raman Spectrometer offers research laboratory-level spectroscopic performance. It includes an open architecture that allows custom coupling to almost any equipment in any position. This coupling eliminates the need for multiple measurements and assumptions, enabling users to get quick and accurate answers.
Data captured simultaneously under the same condition from multiple techniques enables researchers to obtain the precise, reliable data they need. This makes it possible to learn about a sample’s physical, chemical, and structural characteristics and how they affect one another all from one measurement.
Other features include:
The DXR3 Flex Raman Spectrometer can be coupled with many other techniques and equipment including:
Additional applications for the DXR3 Flex Raman Spectrometer include: automotive and aerospace for failure analysis of parts, development of lighter but stronger materials; cosmetics for dyes and impurities analysis; life science and bio-materials for protein structure determination, and general identification of biomolecules; as well as, in material science, biological studies, and many applied research fields within academic research.
Publications
Singh, H., Marley-Hines, M., Chakravarty, S., & Nath, M. (2022). Multi-walled carbon nanotube supported manganese selenide as a highly active bifunctional OER and ORR electrocatalyst. Journal of Materials Chemistry A.
Andrade, A. M., Liu, Z., Grewal, S., Nelson, A. J., Nasef, Z., Diaz, G., & Lee, M. H. (2021). MOF-derived Co/Cu-embedded N-doped carbon for trifunctional ORR/OER/HER catalysis in alkaline media. Dalton Transactions, 50(16), 5473-5482.
Drapcho, D., Plog, J. P., & Crawford, N. C. (2017). Monitoring Polymer Phase Transitions by Combining Rheology and Raman Spectroscopy.
Vehmas, T., Myllykylä, E., Nieminen, M., Laatikainen-Luntama, J., Leivo, M., & Olin, M. (2020, April). Geopolymerisation of gasified ion-exchange resins, mechanical properties and short-term leaching studies. In IOP Conference Series: Materials Science and Engineering (Vol. 818, No. 1, p. 012017). IOP Publishing.
Documents
For Research Use Only. Not for use in diagnostic procedures.