Numerical and Experimental Investigations of Cesium and Strontium Sorption and Transport in Agricultural Soils

Numerical and Experimental Investigations of Cesium and Strontium Sorption and Transport in Agricultural Soils

Core Ideas Cation exchange (CE) on illite, a main sorption process for Cs+, is driven by Cs+ concentration. Undefined CE and surface complexation on OM are main sorption processes for Sr2+. 137Cs+ migrated only into shallow depths of a few centimeters after 3 yr. 90Sr2+ migrated into deeper layers o...

Full description

Saved in:
Bibliographic Details
Published in:Vadose zone journal Vol. 17; no. 1; pp. 1 - 14
Main Authors: Berns, Anne E., Flath, Alexander, Mehmood, Khalid, Hofmann, Diana, Jacques, Diederik, Sauter, Martin, Vereecken, Harry, Engelhardt, Irina
Format: Journal Article
Language:English
Published: Madison The Soil Science Society of America, Inc 2018
John Wiley & Sons, Inc
Wiley
Subjects:
Agricultural land
Alternative energy sources
Bioavailability
Caesium
Caesium 137
Calcium ions
Cation exchange
Cation exchanging
Cations
Cesium
Cesium 137
Cesium isotopes
Cesium radioisotopes
Climatic conditions
Coefficients
Complexation
Depth
Experiments
Groundwater
Humid climates
Identification
Illite
Illites
Leaching
Liquor
Loam
Loam soils
Magnesium
Minerals
Nuclear reactors
Organic matter
Radiation
Radioisotopes
Radionuclide kinetics
Sandy loam
Saturation
Silt loam
Simulation
Soil
Soil conditions
Soil layers
Soil properties
Soil texture
Soils
Sorption
Strontium
Texture
Transport
Germany
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Core Ideas Cation exchange (CE) on illite, a main sorption process for Cs+, is driven by Cs+ concentration. Undefined CE and surface complexation on OM are main sorption processes for Sr2+. 137Cs+ migrated only into shallow depths of a few centimeters after 3 yr. 90Sr2+ migrated into deeper layers of the soil due to competitive sorption. A process‐based knowledge of the sorption mechanisms in soils is a prerequisite for the prediction of radionuclide transport in soils, plant availability, and leaching risk into groundwater. The present study combined batch sorption experiments of Cs+ and Sr2+ in agricultural soils of differing soil texture with numerical experiments using PHREEQC to identify key processes of sorption at different temperatures. Sorption was simulated for both radionuclides using cation exchange models. In addition, surface complexation was integrated into the reaction network for Sr2+. Our geochemical simulations identified cation exchange on illite as the dominant sorption process for Cs+. Selection of the site types in Cs+ sorption was mainly driven by Cs+ concentration. At low Cs+ concentrations the highly selective frayed edge sites dominated sorption behavior, while less affine site types on illite constituted the major sorption partners at high concentrations. We identified undefined cation exchange as the dominant sorption process for Sr2+, followed by surface complexation on organic matter. These process‐based analyses were the basis for field‐scale simulations to predict the leaching risk of Cs and Sr radionuclides in agricultural soils under humid climate conditions. For both soils and radionuclides, the distribution coefficients (Kd) varied distinctly with time in shallow layers due to changes in temperature, saturation, and the prevailing dominant sorption processes. During a 3‐yr‐simulation period, 137Cs+ migrated to depths of 3.6 cm (silty loam) and 7.6 cm (sandy loam), while 90Sr2+ migrated to depths of 15.6 cm (silty loam) and 23.6 cm (sandy loam) due to competitive sorption of infiltrating Ca2+ and Mg2+ ions reducing 90Sr2+ sorption and displacing 90Sr2+ from its exchange sites.
Bibliography:Supplemental material online.
ISSN:1539-1663
1539-1663
DOI:10.2136/vzj2017.06.0126