The features of Cs sorption onto peaty-podzolic-gleyic soil

Chemosphere. 2023 Oct:339:139580. doi: 10.1016/j.chemosphere.2023.139580. Epub 2023 Jul 20.

Abstract

This article studies sorption regularities and estimates the strength of 137Cs fixation by various soil horizons in peaty-podzolic-gleyic soils under a model experiment. The interaction time varied from 1 week to 3 months while Cs concentration varied from trace to micromolar concentrations. To understand the interaction mechanisms of cesium with individual soil components, we used the method of sequential removal of organic matter and non-silicate iron compounds from the soil before the sorption experiment. Illite and vermiculite were found to be the main soil components for radiocesium sorption in the mineral soil horizons. The highly selective positions (FES - frayed edge sites) of the abovementioned minerals fixed radiocesium so strongly that even strong acid solutions could not extract it from soil. Organic matter significantly contributed to the fixation of radiocesium in the soil only in the ELih horizon which contained 4.71% Corg. In the ELg horizon, a small amount of organic matter was able to inhibit sorption by blocking highly selective to radiocesium FES. The Tessier sequential extraction method of radiocesium revealed that all the studied soil samples could strongly fix the radionuclide. Increasing the interaction period up to three months under periodic wetting and drying contributed to the increased proportion of strongly bound 137Cs. The results of sorption experiments carried out before and after the removal of non-silicate iron compounds from the soil indicate that 137Cs has little or no sorption on the surface of iron hydroxides.

Keywords: Cesium; Clay; Partitioning; Radionuclides; Soil; Sorption.

MeSH terms

  • Adsorption
  • Cesium
  • Cesium Radioisotopes / analysis
  • Soil Pollutants, Radioactive* / analysis
  • Soil*

Substances

  • Soil
  • Cesium-137
  • Soil Pollutants, Radioactive
  • Cesium Radioisotopes
  • Cesium