Vol. 32, issue 12, article # 7

Orlovskii V. M., Panarin V. A., Ripenko V. S. Temporal changes in the IR spectra of distilled and heavy water after irradiation by a nanosecond electron flux. // Optika Atmosfery i Okeana. 2019. V. 32. No. 12. P. 990–993. DOI: 10.15372/AOO20191207 [in Russian].
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Abstract:

The absorption spectra of distilled and heavy water after treatment by a nanosecond electron flux are examined. A change in the absorption spectrum of the substance was recorded after multiple treatment of water. The analysis of the IR absorption spectra of water showed the difference between the absorption spectra of non-irradiated and irradiated water and а change in the latter over time.

Keywords:

nanosecond electron flux, water absorption spectrum in infrared region, water conductivity

References:

  1. Bessonova A.P., Stas I.E. Effect of high-frequency electromagnetic fields on physical chemist properties of water and its spectral characteristics // Polzunovskii vestnik. 2008. N 3. P. 305–309.
  2. Classen V.I. Omagnichevanie water systems. M.: Chemistry, 1973. 239 p.
  3. Zenin S.V., Тyaglov B.V. Hydrophobic model of the structure of water molecules associates // Zh. Fiz. Himii. 1994. V. 68, N 4. P. 636–641.
  4. Orlovskii V.M., Panarin V.А., Shulepov M.A. Change water, aqueous solutions and dielectric films diffuse discharge being generated preionization by fast electrons when a voltage pulse shorter front // Tech. Phys. Lett. 2015. V. 41, N 23. P. 81–88.
  5. Orlovskii V.M., Panarin V.A., Shulepov M.A. The formation of diffuse discharge by short-front nanosecond voltage pulses and the modification of dielectrics in this discharge // Tech. Phys. Lett. 2014. V. 40, N 7. P. 645–648.
  6. Orlovskii V.M., Alekseev S.B., Tarasenko V.F. Carbon dioxide lazer with an e-beam-initiated discharge produced in a pressure up to 5 atm // Quant. Elektron. 2011. V. 41, N 11. P. 1033–1036.
  7. Lugovskoy A.A., Poplavskii Yu.A., Serdyukov V.I., Sinitsa L.N. Experimental setup for spectrophotometric study of water clusters in nanoporous material // Atmos. Ocean. Opt. 2011. V. 24, N 5. P. 502–507.
  8. Voronina T.V., Semenov V.G. Organization of the control of the isotopic composition of heavy water at PIK reactor by IR-spectrometry // Sci. Comput. Instrum. 2012. V. 22, N 1. P. 84–90.
  9. Voronina T.V., Slobodov А.А. Spectroscopic and thermodynamic study of heavy water // J. Opt. Technol. 2011. V. 78, N 3. P. 3–9.
  10. Orlovskij V.M., Panarin V.A. Izmenenie IK-spektrov pit'evoj vody, taloj vody iz snega i tyazheloj vody pri obluchenii elektronnym potokom nanosekundnoj dlitel'nosti // Optika atmosf. i okeana. 2018. V. 31, N 3. P. 240–243; Orlovskii V.M., Panarin V.A. Changes in the IR spectra of drinking water, melt water from snow, and heavy water irradiated by a nanosecond electron beam // Atmos. Ocean. Opt. 2018. V. 31, N 3. P. 386–389.
  11. Pikaev А.K. Modern Radiation Chemistry. The radiolysis of gases and liquids. Moscow: Science, 1986. 440 p.