Keywords

Bismuth, Electrorefining, Waveform, Efficiency, Yield

Abstract

Electrorefining in molten salts is used for purifying actinides. Optimizing electrorefining is key to minimizing processing time and radiological waste. One possible way of improving electrorefining efficiency is using an AC superimposed DC waveform. This waveform has demonstrated potential benefits in aqueous solutions but has never been utilized in a molten metal, molten salt application. This work investigates the effects of using an AC superimposed DC waveform on molten bismuth electrorefining in a molten LiCl–KCl–CaCl2 eutectic. Bismuth has been identified as a potential surrogate for plutonium electrorefining and a potential cathode in electrorefining used nuclear fuel (UNF). All electrorefining runs resulted in a high purity cathode ring and high yield with exception of the run using a low-frequency, high-amplitude superimposed AC waveform, which experienced some contamination and a lower yield. The other three AC superimposed DC runs experienced an average yield 6.7 % higher than the average yield of the DC runs. The electrorefining run using the high-frequency, high-amplitude superimposed AC signal had the highest yield. It is recommended in future studies to investigate the statistical variability of electrorefining yield and current efficiency and the impact of AC superimposed DC waveforms on solidified bismuth anodes.

Original Publication Citation

Greg Chipman, Bryant Johnson, Devin Rappleye, Application of AC superimposed DC waveforms to bismuth electrorefining, Nuclear Engineering and Technology, Volume 56, Issue 4, 2024, Pages 1339-1346, ISSN 1738-5733, https://doi.org/10.1016/j.net.2023.11.038.

Document Type

Peer-Reviewed Article

Publication Date

2023-11-23

Publisher

Elsevier

College

Ira A. Fulton College of Engineering

Department

Chemical Engineering

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