Vol. 31, issue 03, article # 16

Orlovskii V.M., Panarin V.A. Changes in the IR spectra of drinking water, melt water from snow, and heavy water by nanosecond electron beam irradiation. // Optika Atmosfery i Okeana. 2018. V. 31. No. 03. P. 240–243 [in Russian].
Copy the reference to clipboard

The absorption spectra of drinking water, melt water from snow, and heavy water during irradiated by nanosecond electron flux are studied. Under repeated irradiation of water, a change in the absorption spectrum of a substance was observed. The a analysis of water absorption spectra in the IR range showed differences between the absorption spectra of irradiated and non-irradiated water.


nanosecond electron flow, water absorption spectrum in the infrared region, water conductivity


  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. Magnetization of 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 // Quantum Electron. 2011. V. 41, N 11. P. 1033–1036.
  7. Lugovskoj A.A., Poplavskij Ju.A., Serdjukov V.I., Sinica L.N. Jeksperimental'naja ustanovka dlja spektrofotometricheskogo issledovanija klasterov vody v nanoporah // Optika atmosf. i okeana. 2011. V. 24, N 5. P. 418–424; 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. Pikaev А.K. Modern Radiation Chemistry. The radiolysis of gases and liquids. M: Science, 1986. 440 p.
  11. Orlovskii` V.M., Panarin V.A. Dynamics of changes in the infrared spectrum of distilled and heavy water upon exposureto an electron beam of nanosecond duration // Tech. Phys. Lett. 2017. V. 43, N 12. P. 1054–1056.