Publication detail

Uranium detection by 3D-printed titanium structures: Towards decentralized nuclear forensic applications

URBANOVÁ, V. PUMERA, M.

Original Title

Uranium detection by 3D-printed titanium structures: Towards decentralized nuclear forensic applications

Type

journal article in Web of Science

Language

English

Original Abstract

Uranium can cause significant pollution of the ecosystem as well as it can have immense hazardous effect on human health due to its chemical and radioactive toxicity. Uranyl ions (UO22+) are considered as the most common and stable ionic form of uranium and additionally, UO22+ can spread easily through the environment owing to their high solubility and mobility in water. Hence, the development of appropriate sensors for UO22+ detection is very important for in time revelation of potentially dangerous sources of water or soil contamination. 3D-printing technology is now recognized as effective tool for designing and manufacturing objects of different sizes and shapes. Thus, it might also offer customized solution for design of electrodes to be applied in environmental sensing. In this work, 3D-printed titanium electrode was evaluated toward uranyl ions determination in aqueous samples. This electrode revealed good liner response within the wide concentration range, high stability as well as reproducibility. Good analytical performance of 3D-Ti electrode was further confirmed by low detection limit of 24.5 mu g L-1 that also meets the requirement of Maximum Contaminant Level (MCL) for uranium in drinking water (30 mu g L-1). The performance of 3D-Ti electrode was also evaluated for its capability of UO22+ determination in spiked tap and mineral water. All results presented in this work, encourage and highlight the exploitation of 3D-printing technology for electrochemical sensing applications since it has strong potential for environmental, nuclear forensic and security applications. (C) 2020 Elsevier Ltd. All rights reserved.

Keywords

Additive manufacturing; Uranium; Analytical chemistry

Authors

URBANOVÁ, V.; PUMERA, M.

Released

1. 12. 2020

Publisher

ELSEVIER

Location

AMSTERDAM

ISBN

2352-9407

Periodical

Applied Materials Today

Year of study

21

Number

1

State

Kingdom of the Netherlands

Pages from

100881-1

Pages to

100881-5

Pages count

5

URL

https://www.sciencedirect.com/science/article/pii/S2352940720303292?via%3Dihub