A wide-range Raman shift wavenumber measure based on a polymer material.
- Autores: Alenichev M.K.1, Yushina A.A.1
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Afiliações:
- All Russian Scientific and Research Institute for Optical and Physical Measurement
- Edição: Volume 74, Nº 1 (2025)
- Páginas: 77-82
- Seção: OPTOPHYSICAL MEASUREMENTS
- URL: https://journal-vniispk.ru/0368-1025/article/view/328001
- ID: 328001
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Resumo
The wave number of the Raman shift is one of the most important parameters in Raman spectroscopy. Since the accuracy of determining the wave number of the Raman shift strongly depends on the technical characteristics of the Raman spectrometers and the measurement conditions, physically and chemically stable reference materials that would be convenient for users are required to calibrate such devices on the wave number scale. One of the promising areas of development of such reference materials that meet these requirements are solid-state reference materials developed in our country and abroad. A Raman shift wave number measure has been developed and tested for the purpose of approving the type of measuring instrument. The measure is intended for calibration and verification of measuring instruments on the scale of Raman shift wave numbers. The measure is a polymer film consisting of polystyrene and sulfur and placed in a special mandrel. The measure material is in a solid aggregate state. The metrological characteristics of the developed measure have been studied. It has been established that the measure allows storing and transmitting a unit of Raman shift wave numbers for Raman scattering excitation wavelengths of 532–785 nm in the range of 80–3000 cm–1 with an error of no more than 1 cm–1. Traceability is ensured to the State primary special standard of units of energy, energy density distribution, pulse duration and wavelength of laser radiation GET 187-2016 and the State working standard of the unit of wavelength for fiber-optic information transmission systems in the range of values from 0.4 to 3.4 μm (3.1.ZZA.0114.2018). The combination of polystyrene and sulfur lines in the Raman spectrum of the developed measure made it possible to expand (in comparison with the range of similar solid-state measures of foreign production) the range of wave numbers of Raman shifts, especially in the short-wave region.
Sobre autores
M. Alenichev
All Russian Scientific and Research Institute for Optical and Physical Measurement
Email: alenichev@bk.ru
ORCID ID: 0000-0001-6336-8900
A. Yushina
All Russian Scientific and Research Institute for Optical and Physical Measurement
Email: leighstranger@yandex.ru
Bibliografia
Workman Jr. J. The 2023 emerging leader in molecular spectroscopy award. Spectroscopy, 38(9), 33–38 (2023). https://doi.org/10.56530/spectroscopy.bu5978k6 Еремина О. Е., Семенова А. А., Сергеева Е. А., Браже Н. А., Максимов Г. В., Шеховцова Т. Н., Гудилин Е. А., Веселова И. А. Спектроскопия гигантского комбинационного рассеяния в современном химическом анализе: достижения и перспективы использования. Успехи химии, 87(8), 741–770 (2018). https://doi.org/10.1070/rcr4804 Petersen M., Yu Z., Lu X. Application of Raman spectroscopic methods in food safety: a review. Biosensors, 11(6), 187 (2021). https://doi.org/10.3390/bios11060187 Benattia F. K., Arrar Z., Dergal F. Methods and applications of Raman Spectroscopy: a powerful technique in modern research, diagnosis, and food quality control. Current Nutrition & Food Science, 20(1), 41–61 (2024). https://doi.org/10.2174/1573401319666230503150005 Ntziouni A., Thomson J., Xiarchos I., Li X., Banares M. A., Charitidis C., Portela R., Diz E. L. Review of existing standards, guides, and practices for Raman spectroscopy. Applied Spectroscopy, 76(7), 747–772 (2022). https://doi.org/10.1177/00037028221090988 Itoh N., Hanari N. Development of a polystyrene reference material for Raman spectrometer (NMIJ RM 8158-a). Analytical Sciences, 37(11), 1533–1539 (2021). https://doi.org/10.2116/analsci.21P054
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