Your search keyword '"Romanchuk, A. Y."' showing total 4 results

1. High surface area '3D Graphene Oxide' for enhanced sorption of radionuclides

Author

Boulanger, N., Kuzenkova, A. S., Iakunkov, A., Nordenström, A., Romanchuk, A. Y., Trigub, A. L., Zasimov, P. V., Podana, M., Enachescu, M., Bauters, S., Amidani, L., Kvashnina, K. O., Kalmykov, S. N., and Talyzin, A. V.

Abstract

Earlier studies demonstrated that graphene oxide (GO) with large number of defects is favorable for the sorption of radionuclides. Here we report oxidation treatment which converts high surface area activated reduced graphene oxide (arGO) into a 3D analogue of defect-rich GO (dGO). Oxidation of arGO using ammonium persulfate results in oxidation corresponding to carbon to oxygen ratio C/O=3.3, similar to the oxidation state of graphene oxide while preserving high BET surface area of about 880 m2/g. Analysis of surface oxidized arGO shows high abundance of oxygen functional groups very similar to dGO and hydrophilic properties. The “3D graphene oxide” showed high sorption capacity for U(VI) removal in an extraordinary broad interval of pH. Notably, the surface oxidized carbon material has a rigid 3D structure with micropores accessible for penetration of radionuclide ions. Therefore, the bulk “3D GO” can be used as a sorbent directly without dispersing, the step required for GO to make its surface area accessible for pollutants

Published

2022

2. The application of HEXS and HERFD XANES for accurate structural characterization of actinide nanomaterials: application to ThO₂

Author

Amidani, L., Vaughan, G. B. M., Plakhova, T. V., Romanchuk, A. Y., Gerber, E., Svetogorov, R., Weiß, S., Joly, Y., Kalmykov, S. N., and Kvashnina, K.

Subjects

HEXS, actinides, nanoparticles, ThO₂, HERFD

Abstract

Structural characterization of actinide nanoparticles (NPs) is of primary importance and hard to achieve, especially for non‐homogeneous samples with NPs below 3 nm. By combining High Energy X‐ray Scattering (HEXS) and High‐Energy‐Resolution Fluorescence Detected X‐ray Near‐Edge Structure (HERFD XANES), we characterized for the first time both short‐ and medium‐range order of ThO₂ NPs obtained by chemical precipitation. With this methodology, a novel insight into the structure of NPs at different steps of their formation process is achieved. The Pair Distribution Function (PDF) reveals a high concentration of ThO₂ small units similar to Th hexamer clusters mixed with 1 nm ThO₂ NPs in the initial steps of formation. Drying the precipitates at ⁓150 °C promotes recrystallization of the smallest units into more thermodynamically stable ThO₂ NPs. HERFD XANES at Th M₄ edge, a direct probe of the f states, shows variations that we correlate to the break of the local symmetry around Th atoms, which most likely concerns surface atoms. Together, HEXS and HERFD are a powerful methodology to investigate actinide NPs and their formation mechanism.

Published

2021

3. Towards the surface hydroxyl species in CeO2 nanoparticles

Author

Plakhova, T. V., Romanchuk, A. Y., Butorin, S. M., Konyukhova, A. D., Egorov, A. V., Shiryaev, A. A., Baranchikov, A. E., Dorovatovskii, P. V., Huthwelker, T., Gerber, E., Bauters, S., Sozarukova, M. M., Scheinost, A., Ivanov, V., Kalmykov, S. N., and Kvashnina, K.

Abstract

Understanding the complex chemistry of functional nanomaterials is of fundamental importance. Controlled synthesis and characterization at the atomic level is essential to gain deeper insight into the unique chemical reactivity exhibited by many nanomaterials. Cerium oxide nanoparticles have many industrial and commercial applications, resulting from very strong catalytic, pro- and anti-oxidant activity. However, the identity of the active species and the chemical mechanisms imparted by nanoceria remain elusive, impeding the further development of new applications. Here, we explore the behavior of cerium oxide nanoparticles of different sizes at different temperatures and trace the electronic structure changes by state-of-the-art soft and hard X-ray experiments combined with computational methods. We confirm the absence of the Ce(III) oxidation state at the surface of CeO2 nanoparticles, even for particles as small as 2 nm. Synchrotron X-ray absorption experiments at Ce L3 and M5 edges, combined with X-ray diffraction (XRD), high-resolution transmission electron microscopy (HRTEM) and small angle X-ray scattering (SAXS) and theoretical calculations demonstrate that in addition to the nanoceria charge stability, the formation of hydroxyl groups at the surface profoundly affects the chemical performance of these nanomaterials.

Published

2019

4. Understanding the size effects on the electronic structure of ThO2 nanoparticles

Author

Amidani, L., Plakhova, T. V., Romanchuk, A. Y., Gerber, E., Weiss, S., Efimenko, A., Sahle, C. J., Butorin, S. M., Kalmykovc, S. N., and Kvashnina, K. O.

Abstract

Developing characterization techniques and analysis methods adapted to the investigation of nanoparticles (NPs) is of fundamental importance considering the role of these materials in many fields of research. The study of actinide based NPs, despite their environmental relevance, is still underdeveloped compared to that of NPs based on stable and lighter elements. We present here an investigation of ThO2 NPs performed with High-Energy Resolution Fluorescence Detected (HERFD) X-ray Absorption Near-Edge Structure (XANES) and with ab initio XANES simulations. Structural models of ThO2 NPs with sharp edges and corners reproduce the size effect observed in experimental data. Inspection of the simulations from Th atoms in the core and on the surface of the NP indeed demonstrates that the origin of the effect is the lowering of the number of coordinating atoms for Th at the surface of the NP. The sensitivity of HERFD XANES to the less coordinated atoms at the surface may be exploited to investigate surface interactions.

Published

2019