Mechanistic understanding of Curium(III) sorption on natural K-feldspar surfaces.

Maximilian Demnitz, Stefan Schymura, Julia Neumann, Moritz Schmidt, Thorsten Schäfer, Thorsten Stumpf, Katharina Müller

The Science of the total environment 2022 Oct 15

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To assess a reliable safety case for future deep underground repositories for highly active nuclear waste the retention of radionuclides by the surrounding host rock must be understood comprehensively. Retention is influenced by several parameters such as mineral heterogeneity and surface roughness, as well as pore water chemistry (e.g., pH). However, the interplay between those parameters is not yet well understood. Therefore, we present a correlative spectromicroscopic approach to investigate sorption of the actinide Cm(III) on: 1) bulk K-feldspar crystals to determine the effect of surface roughness and pH (5.5 and 6.9) and 2) a large feldspar grain as part of a complex crystalline rock system to observe how sorption is influenced by the surrounding heterogeneous mineralogy. Our findings show that rougher K-feldspar surfaces exhibit increased Cm(III) uptake and stronger complexation. Similarly, increasing pH leads to higher surface loading and stronger Cm(III) binding to the surface. Within a heterogeneous mineralogical system sorption is further affected by neighboring mineral dissolution and competitive sorption between mineral phases such as mica and feldspar. The obtained results express a need for investigating relevant processes on multiple scales of dimension and complexity to better understand trivalent radionuclide retention by a potential repository host rock. Copyright © 2022 Elsevier B.V. All rights reserved.

Citation

Maximilian Demnitz, Stefan Schymura, Julia Neumann, Moritz Schmidt, Thorsten Schäfer, Thorsten Stumpf, Katharina Müller. Mechanistic understanding of Curium(III) sorption on natural K-feldspar surfaces. The Science of the total environment. 2022 Oct 15;843:156920