Article
Article name Detection of Ice 0 in Various Synthetic and Natural Environments
Authors Orlov A.O. , Orlov_A_O@mail.ru
Bibliographic description Orlov A. O. Detection of Ice 0 in Various Synthetic and Natural Environments / / Scholarly Notes of Transbaikal State University. 2020. Vol. 15, No. 3. PP. 122-133. DOI: 10.21209/2658- 7114-2020-15-3-122-133.
Section MATHEMATICAL MODELS. EXPERIMENT
UDK 538.915, 538.956
DOI 10.21209/2658-7114-2020-15-3-122-133
Article type
Annotation Studies of a new modification of crystalline ice - ice 0, which can be formed only from supercooled water, have been performed. To do this, experiments were conducted with various porous media, artificial and natural, containing water in the pores of nanometer sizes. The dielectric parameters of the media, as well as some of their electrical properties, were measured. These include reflection coefficients of the radiation of moistened silicates at a frequency of 12, 4 GHz and absorption in pine branches and needles at a frequency of 5,3 GHz, dielectric loss tangent of silicate sorbents at frequencies from hundreds of hertz to hundreds of kHz, intrinsic electrical fluctuations in a frequency band of 1 Hz... 100 Hz and transmitting visible electromagnetic radiation through samples of transparent dielectrics with a thin layer of ice on their surface. The temperature range for different experiments reached values from +20 to -170 °C. An increase in the intensity of absorbed (scattered) radiation at a wavelength of 0, 52 gm was detected. Near the temperatures -20 ... — 24 °C, sharp changes were found in the parameters of moistened silicates and pine wood, which can be explained by the formation or destruction of ferroelectric ice 0. Two possible reasons for this behavior of the parameters during ice formation 0 are stated. This is the appearance of a highly conductive layer at the contact of ferroelectric ice with another dielectric, as well as the appearance of surface plasmons in this layer.
Key words ice 0, supercooled water, remote sensing, ferroelectricitv, electromagnetic properties
Article information
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