Safeguard monitoring of direct electrolytic reduction

Update Item Information
Publication Type thesis
School or College College of Mines & Earth Sciences
Department Metallurgical Engineering
Author Jurovitzki, Abraham L
Title Safeguard monitoring of direct electrolytic reduction
Date 2015-12
Description Nuclear power is regaining global prominence as a sustainable energy source as the world faces the consequences of depending on limited fossil based, CO2 emitting fuels. A key component to achieving this sustainability is to implement a closed nuclear fuel cycle. Without achieving this goal, a relatively small fraction of the energy value in nuclear fuel is actually utilized. This involves recycling of spent nuclear fuel (SNF) - separating fissile actinides from waste products and using them to fabricate fresh fuel. Pyroprocessing is a viable option being developed for this purpose with a host of benefits compared to other recycling options, such as PUREX. Notably, pyroprocessing is ill suited to separate pure plutonium from spent fuel and thus has non-proliferation benefits. Pyroprocessing involves high temperature electrochemical and chemical processing of SNF in a molten salt electrolyte. During this batch process, several intermediate and final streams are produced that contain radioactive material. While pyroprocessing is ineffective at separating pure plutonium, there are various process misuse scenarios that could result in diversion of impure plutonium into one or more of these streams. This is a proliferation risk that should be addressed with innovative safeguards technology. One approach to meeting this challenge is to develop real time monitoring techniques that can be implemented in the hot cells and coupled with the various unit operations involved with pyroprocessing. Current state of the art monitoring techniques involve external chemical assaying which requires sample removal from these unit operations. These methods do not meet International Atomic Energy Agency's (IAEA) timeliness requirements. In this work, a number of monitoring techniques were assessed for their viability as online monitoring tools. A hypothetical diversion scenario for the direct electrolytic reduction process was experimentally verified (using Nd2O3 as a surrogate for PuO2). Electrochemical analysis was demonstrated to be effective at detecting even very dilute concentrations of actinides as evidence for a diversion attempt.
Type Text
Publisher University of Utah
Subject Electrolytic Reduction; Molten Salt; Pyroprocessing; Safeguards
Dissertation Institution University of Utah
Dissertation Name Master of Science
Language eng
Rights Management Copyright © Abraham L Jurovitzki 2015
Format Medium application/pdf
Format Extent 27,650 bytes
Identifier etd3/id/4012
ARK ark:/87278/s6qc3btv
Setname ir_etd
ID 197562
Reference URL https://collections.lib.utah.edu/ark:/87278/s6qc3btv