The demand for americium dioxide stems from the difficulty of storing the element americium as a solution of americium(III) chloride because the alpha radiation and hydrochloric acid decomposes storage containers over time. To solve the liquid storage problem, scientists at Oak Ridge National Laboratory devised a synthesis to turn liquid americium–acid solution into a precipitated form of americium for safer handling and more efficient storage.[4]
Synthesis
Synthesis of americium dioxide, as described by the Oak Ridge National Laboratory in 1960, starts by dissolving americium in hydrochloric acid, and then neutralizing the excess acid with ammonium hydroxide (NH 4OH). Then, saturated oxalic acid solution (C 2H 2O 4) is added to the now neutralized solution to precipitate dull pink americium(III) oxalate crystals; once complete precipitation is achieved, additional oxalic acid is added to make a slurry. The slurry of americium oxalate and oxalic acid is next agitated before the americium oxalate is filtered out, washed with water, and partially dried in air.[4]
The americium oxalate is then calcinated in a platinum boat. It is first dried in a furnace at 150 °C (302 °F) and then heated to 350 °C (662 °F). When decomposition begins to occur, the oxalate will turn into the desired black americium dioxide; to ensure no oxalate remains in the newly forming dioxide, the oven temperature is increased and held at 800 °C (1,470 °F) then slowly allowed to cool to room temperature.[4]
Modern applications
Americium dioxide is the most widely used americium compound in ionising smoke detectors. The dioxide form is insoluble in water, making it relatively safe to handle in production.
Americium-aluminium alloys can be formed by melting americium dioxide with aluminium and an additional fluxing agent.[6] The created alloy can undergo neutron irradiation to produce other transuranicnuclides.[7]
References
^ abChristine Guéneau; Alain Chartier; Paul Fossati; Laurent Van Brutzel; Philippe Martin (2020). "Thermodynamic and Thermophysical Properties of the Actinide Oxides". Comprehensive Nuclear Materials 2nd Ed. 7: 111–154. doi:10.1016/B978-0-12-803581-8.11786-2. ISBN9780081028667. S2CID261051636.