Abstract
Electrical power sources used in outer planet missions are a key enabling technology for data acquisition and communications. State–of-the-art power sources generate electricity from alpha decay of 238 Pu via thermoelectric conversion. However, production of 238 Pu requires specialist facilities including a nuclear reactor, a source of 237 Np for target irradiation and hotcells to chemically separate neptunium and plutonium within the irradiated targets. These specialist facilities are expensive to build and operate, so naturally, a more economical alternative is attractive to the industry. Within Europe 241Am is considered a promising alternative heat source for radioisotope thermoelectric generators (RTGs) and radioisotope heating units (RHUs). As a daughter product of 241 Pu decay, 241 Am exists in 1000 kgs quantities within the UK civil plutonium stockpile.A chemical separation process is required to extract the 241 Am in a pure form and this paper describes the AMPPEX process (Americium and Plutonium Purification by Extraction), successfully developed over the past five years to isolate 241 Am in high yield (> 99%) and to a high purity (> 99%).The process starts by dissolving plutonium dioxide in nitric acid with the aid of a silver(II) catalyst, which is generated electrochemically. The solution is then conditioned and fed to a PUREX type solvent extraction process, where the plutonium is separated from the americium and silver. The plutonium is converted back to plutonium dioxide and the americium is fed forward to a second solvent extraction step. Here the americium is selectively extracted leaving the silver in the aqueous phase. The americium is stripped from the solvent and recovered from solution as americium oxalate, which is calcined to give americium dioxide as the final product. This paper will describe the development of the separation process over a series of six solvent extraction separation trials using centrifugal contactors. The material produced (~ 4g 241 Am) was used to make ceramic pellets to establish the behaviour of americium oxide material under high temperature (1450°C) sintering conditions.The chemical separation process is now demonstrated at concentrations expected on the full scale facility taking this process to TRL 4-5.
Highlights
INTRODUCTIONOver the last few years there has been an interest by the European Space Agency (ESA) to develop power systems for space missions within Europe [1] and a study was initiated to explore the development of radioisotope powered systems suitable for producing heat and electrical power
A chemical separation process is required to extract the 241Am in a pure form and this paper describes the AMPPEX process (Americium and Plutonium Purification by Extraction), successfully developed over the past five years to isolate 241Am in high yield (> 99%) and to a high purity (> 99%)
Over the last few years there has been an interest by the European Space Agency (ESA) to develop power systems for space missions within Europe [1] and a study was initiated to explore the development of radioisotope powered systems suitable for producing heat and electrical power
Summary
Over the last few years there has been an interest by the European Space Agency (ESA) to develop power systems for space missions within Europe [1] and a study was initiated to explore the development of radioisotope powered systems suitable for producing heat and electrical power. Some of the plutonium has been stored for many decades and one of the isotopes (241Pu), present within the plutonium, has beta decayed to the isotopically pure 241Am. A programme of work was initiated by ESA in 2009 to develop a process to isolate 241Am from plutonium dioxide (PuO2) [2, 3], while separate parallel studies established how the isotope would be incorporated in to power systems [4]. This paper provides an overview of the radioisotope production aspects of the programme
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