Recovery of Organomineral Gel Properties in Dried Soil Samples

Based on earlier study results, the drying process changes the soil properties and, in particular, the characteristic features of a specific soil organic material such as a humic substance (HS). HS is the basis of soil organomineral gels that cover and bind soil particles. When water is removed from...

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Published inDoklady earth sciences Vol. 517; no. 1; pp. 1255 - 1261
Main Authors Fedotov, G. N., Shoba, S. A., Ushkova, D. A., Gorepekin, I. V., Salimgareeva, O. A., Sukharev, A. I.
Format Journal Article
LanguageEnglish
Published Moscow Pleiades Publishing 2024
Springer Nature B.V
Subjects
Air
Compression
Drying
Earth and Environmental Science
Earth Sciences
Electron microscopy
Freezing
Gels
Humic substances
Humidification
Lasers
Organic soils
Particle size distribution
Recovery
Scanning electron microscopy
Size distribution
Soil particles
Soil properties
Soil Science
Soil structure
Soil types
Soil water
Ultrasonic imaging
Ultrasonic processing
Ultrasound
Vibration
Viscometry
Viscosity
colloids in soils
air-dried soil samples
dry and moist soils
soil freezing
soil paste viscosity
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Summary:Based on earlier study results, the drying process changes the soil properties and, in particular, the characteristic features of a specific soil organic material such as a humic substance (HS). HS is the basis of soil organomineral gels that cover and bind soil particles. When water is removed from soil, gels are subjected to hydrophobization and compression resulting in changes in properties of soil samples. The recovery of soil gels of air-dried samples should reduce the discrepancy between the study data obtained on the soil properties of dried and non-dried soil samples. The study objective is to find ways to recover the structure of soil gels. Samples of six soil types were studied. Vibration viscometry, laser diffractometry, scanning electron microscopy (SEM), photocolorimetry, and conductometry were used in this work. The drying of soil samples increases the size of supramolecular formations (SMFs) in the soil and reduces the soil paste viscosity, a parameter characterizing the structure and the ability of gels to swell. To recover the structure of soil gels, it is proposed to reduce the size of SMFs from HSs to the initial level. SMFs of air-dried samples were separated by soil moistening and subsequent treatment with various temperatures, by ultrasound, and by freezing. Based on the SEM data, heating and ultrasound treatment do not reduce, but enlarge SMFs. Humidification of air-dried soils, exposure to moisture for two weeks, and subsequent freezing bring the paste viscosity of a number of studied soils closer to the condition of samples that were not dried. This process is due to the return of SMFs to size values of the initial soils, as evidenced by the laser diffractometer data on the suspended particle size distribution. Hence, a method for recovery of gel structures in dried soils to the initial state is proposed.
ISSN:1028-334X
1531-8354
DOI:10.1134/S1028334X24601755