Complex of Cryogenic Apparatus for Infrared Fourier Bruker Vertex 70v Spectrometer

Authors

  • I.P. Zharkov Institute of Physics of the NАS of Ukraine
  • V.V. Safronov Institute of Physics of the NАS of Ukraine
  • V.O. Khodunov Institute of Physics of the NАS of Ukraine
  • V.M. Konoval Institute of Physics of the NАS of Ukraine
  • V.O. Maslov Institute of Physics of the NАS of Ukraine
  • O.V. Selivanov Institute of Physics of the NАS of Ukraine
  • A.G. Solonetsky Institute of Physics of the NАS of Ukraine
  • V.V. Strelchuk Іnstitute of Semiconductors Physics of the NAS of Ukraine
  • A.S. Nikolenko Іnstitute of Semiconductors Physics of the NAS of Ukraine
  • B.I. Tsykaniuk Іnstitute of Semiconductors Physics of the NAS of Ukraine

DOI:

https://doi.org/10.15407/scine15.04.069

Keywords:

Fourier spectrometer, nitrogen cryosystems, temperature-controlled helium

Abstract

Introduction. Infrared Fourier Bruker spectrometer of Vertex 70v type is known to be a high-resolution research device that has a rather high cost. The device manufacturer intends to expand its functional possibilities due to cooperation with western partners with the use of additional attachments to the spectrometer and continuous flow cryostats for temperature dependent measurements.
Problem Statement. The imported attachments are standard-type, not customized and quite expensive. Therefore, the objective of this research is to expand functional capabilities of the spectrometer using Ukraine-made pieces.
Purpose. To design the configuration and to create a cryogenic apparatus for expanding the functional capabilities of Bruker Vertex 70v infrared Fourier spectrometer of (Germany).
Results. The cryogenic apparatus consisting of the cryosystem with temperature controlled within 2.2-330 K based on a helium continuous flow cryostat with a set of special manipulators and the cryosystem with temperature controlled within 80-500 K based on a combined nitrogen cryostat with vacuum refrigerant duct of continuous flow type and integrated reservoir of liquid cryoagent has been created. The developed complex of cryogenic equipment is fully compatible with Bruker Vertex 70v infrared Fourier spectrometer and enables temperature-dependent measurements of infrared transmission, reflection, and photoluminescence spectra.
Conclusions. The designed cryosystems are as good as the best world analogs in terms of technical characteristics and have an essential advantage over them in terms of cryoagent consumption rate.

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Zharkov, I. P., Safronov, V. V., Khodunov, V. O., Konoval, V. M., Maslov, V. O., Selivanov, O. V., Solonetsky, A. G., Strelchuk, V. V., Nikolenko, A. S., Tsykaniuk, B. I., Naseka, V. M. (2017). Expansion of the functional capabilities of the Infrared Fourier Spectrometer Bruker Vertex 70v. Nauka innov., 13(5), 77-82 [in Ukrainian].

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Patent of Ukraine for invention N 87503. Zharkov I. P., Ivashchenko O. M., Safronov V. V., Pogrebnyak S. V. Method and temperature control device [in Ukrainian].

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Published

2024-09-05

How to Cite

Zharkov, I., Safronov, V., Khodunov, V., Konoval, V., Maslov, V., Selivanov, O., Solonetsky, A., Strelchuk, V., Nikolenko, A., & Tsykaniuk, B. (2024). Complex of Cryogenic Apparatus for Infrared Fourier Bruker Vertex 70v Spectrometer. Science and Innovation, 15(4), 69–77. https://doi.org/10.15407/scine15.04.069

Issue

Vol. 15 No. 4 (2019): Science and Innovation

Section

Research and Engineering Innovative Projects of the National Academy of Sciences of Ukraine

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